CN215483612U - Semi-active damper type anti-pulling shock isolation device - Google Patents
Semi-active damper type anti-pulling shock isolation device Download PDFInfo
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- CN215483612U CN215483612U CN202121628892.1U CN202121628892U CN215483612U CN 215483612 U CN215483612 U CN 215483612U CN 202121628892 U CN202121628892 U CN 202121628892U CN 215483612 U CN215483612 U CN 215483612U
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- 230000035939 shock Effects 0.000 title claims abstract description 51
- 238000009413 insulation Methods 0.000 claims abstract description 29
- 230000006835 compression Effects 0.000 claims abstract description 20
- 238000007906 compression Methods 0.000 claims abstract description 20
- 238000003825 pressing Methods 0.000 claims abstract description 6
- 230000000712 assembly Effects 0.000 claims description 41
- 238000000429 assembly Methods 0.000 claims description 41
- 238000004891 communication Methods 0.000 claims description 6
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- 230000000694 effects Effects 0.000 abstract description 16
- 230000004044 response Effects 0.000 abstract description 4
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Abstract
The utility model discloses a semi-active damper type anti-pulling shock isolation device, which comprises: the two ends of the shock insulation support are respectively suitable for being connected with the upper building structure and the lower building structure; the support pulling and pressing sensor is used for detecting the stress state of the shock insulation support; and the two ends of the semi-active damper assembly are respectively suitable for being connected with the upper building structure and the lower building structure and are electrically connected with the support tension and compression sensor, wherein the semi-active damper assembly has a locking state and a telescopic state, and the semi-active damper assembly is set to be switched to the locking state when the seismic isolation support is in a tension state. The semi-active damper type anti-pulling shock isolation device provided by the embodiment of the utility model has good tensile property, can avoid tensile damage of the shock isolation support, meet the anti-pulling shock isolation requirements of high-rise buildings with large height-to-width ratios, improve the horizontal shock isolation effect and reduce the response of the upper structure of the shock isolation support.
Description
Technical Field
The utility model relates to the technical field of civil engineering, in particular to a semi-active damper type anti-pulling shock isolation device.
Background
In the related art, the basic seismic isolation technology is used for seismic resistance of a common building structure, and the input of seismic energy to the building structure is effectively reduced by arranging seismic isolation supports at the bottoms of all columns at the bottom layer of the building structure, so that the safety of the building structure and internal equipment of the building structure are protected.
However, with the development of high-rise buildings, more and more high-rise buildings have seismic isolation requirements. The high-rise building has a large height-width ratio, and under the action of earthquake, due to the action of overturning moment, the edge column member at the bottom of the building is easy to generate pulling force. The building shock insulation support in the related technology has poor tensile property, is difficult to bear the tensile force generated by the overturning of the building, and can generate extremely adverse effect on the building after being damaged by the tensile force.
SUMMERY OF THE UTILITY MODEL
The present invention is directed to solving at least one of the problems of the prior art. Therefore, the utility model aims to provide a semi-active damper type anti-pulling shock insulation device, so that a shock insulation support is not easy to be damaged by tension under the action of an earthquake, and the requirements of high-rise building shock insulation on anti-pulling shock insulation can be met.
According to the embodiment of the utility model, the semi-active damper type anti-pulling shock isolation device comprises: the two ends of the shock insulation support are respectively suitable for being connected with an upper building structure and a lower building structure; the support pulling and pressing sensor is used for detecting the stress state of the shock insulation support; and the two ends of the semi-active damper assembly are respectively suitable for being connected with the upper building structure and the lower building structure and electrically connected with the support tension and compression sensor, wherein the semi-active damper assembly has a locking state and a telescopic state, and is set to be switched to the locking state when the seismic isolation support is in a tension state.
According to the semi-active damper type anti-pulling shock isolation device provided by the embodiment of the utility model, the semi-active damper assembly has the locking state and the telescopic state and is switched to the locking state when the shock isolation support is in the tension state, so that the semi-active damper type anti-pulling shock isolation device has good tensile property, the shock isolation support can be prevented from being damaged by tension, the anti-pulling shock isolation requirement of a high-rise building with a large height-width ratio can be met, the horizontal shock isolation effect can be improved, and the upper structure response of the shock isolation support is reduced. When the semi-active damper assembly is in a telescopic state, the horizontal motion of the shock insulation support is not influenced, and the horizontal shock insulation effect is ensured.
In addition, the semi-active damper type anti-pulling seismic isolation device according to the above embodiment of the utility model may further have the following additional technical features:
according to some embodiments of the utility model, the semi-active damper assembly comprises: an oil cylinder having an oil cavity; the piston rod penetrates through the oil cylinder; a piston mounted to the piston rod and located within the oil chamber to divide the oil chamber into a first chamber and a second chamber; the communicating pipe is connected with the oil cylinder and communicates the first chamber and the second chamber; the control valve is arranged on the communicating pipe and used for controlling the on-off of the communicating pipe, and is electrically connected with the support pulling and pressing sensor, wherein the semi-active damper assembly is in the locking state, and the control valve is closed; the semi-active damper assembly is in the retractable state, the control valve is open.
According to some embodiments of the utility model, the cylinder further has an avoidance chamber, a first end of the piston rod is located outside the cylinder and is connected to one of the upper building structure and the lower building structure, a second end of the piston rod passes through the oil chamber and extends into the avoidance chamber, and an end of the cylinder remote from the first end of the piston rod is connected to the other of the upper building structure and the lower building structure.
According to some embodiments of the utility model, the semi-active damper-type anti-plucking seismic isolation apparatus further comprises: the upper embedded plate and the lower embedded plate are respectively embedded in the upper building structure and the lower building structure and are respectively connected with two ends of the semi-active damper assembly, and the upper embedded plate and the lower embedded plate are respectively positioned at two longitudinal sides of the isolation bearing.
According to some embodiments of the utility model, the semi-active damper assembly is rotatably connected to the upper embedment plate and the lower embedment plate by a gimbal structure.
According to some embodiments of the utility model, the support tension and compression sensor is a distance sensor, and the distance sensor is used for detecting the vertical height of the seismic isolation support, wherein the seismic isolation support is in the tensioned state when the longitudinal height of the seismic isolation support is greater than or equal to a preset distance.
According to some embodiments of the utility model, the support tension and compression sensor is a stress sensor, and the stress sensor is mounted in the seismic isolation support.
According to some embodiments of the utility model, the semi-active damper assemblies are greater than or equal to three, at least three of the semi-active damper assemblies extending upwardly toward or away from each other.
According to some embodiments of the utility model, a plurality of the semi-active damper assemblies are spaced circumferentially along the isolation bearing; or the number of the shock insulation supports is multiple, and each shock insulation support is arranged corresponding to at least one semi-active damper assembly.
According to some embodiments of the utility model, projections of at least two of the semi-active damper assemblies along a first vertical plane are non-parallel to each other and projections of at least two of the semi-active damper assemblies along a second vertical plane are non-parallel to each other, wherein the first vertical plane and the second vertical plane intersect.
Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.
Drawings
The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:
FIG. 1 is a schematic structural view of a semi-active damper type anti-plucking seismic isolation apparatus according to some embodiments of the present invention;
FIG. 2 is a schematic diagram of a semi-active damper-type anti-plucking seismic isolation apparatus according to some embodiments of the present invention;
FIG. 3 is a schematic view of a semi-active damper-type anti-plucking seismic isolation apparatus according to some embodiments of the present invention;
FIG. 4 is a schematic view of a semi-active damper-type anti-plucking seismic isolation apparatus according to some embodiments of the present invention;
FIG. 5 is a front view of a semi-active damper-type anti-plucking seismic isolation apparatus according to some embodiments of the present invention;
FIG. 6 is a front view of a semi-active damper-type anti-plucking seismic isolation apparatus according to some embodiments of the present invention;
FIG. 7 is a schematic diagram of an application structure of a semi-active damper type anti-plucking seismic isolation apparatus according to some embodiments of the present invention;
fig. 8 is a schematic diagram of an application structure of a semi-active damper type anti-plucking seismic isolation apparatus according to some embodiments of the present invention.
Reference numerals:
a semi-active damper type anti-pulling seismic isolation device 100; an upper floor beam 200; a lower floor beam 300; an upper building structure 400; a lower building structure 500;
an upper embedded plate 11; a lower embedded plate 12; a vibration isolation support 13; an upper buttress 131; a lower buttress 132;
a support tension and compression sensor 20; a distance sensor 21; a stress sensor 22;
a semi-active damper assembly 30; an oil cylinder 31; an oil chamber 311; a first chamber 312; a second chamber 313; an avoidance cavity 314; a piston rod 32; a piston 33; the communication pipe 34; a control valve 35; a sphere 36; gimbal structure 37.
Detailed Description
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.
In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the utility model.
In the description of the present invention, "a first feature" or "a second feature" may include one or more of the features, and "a plurality" means two or more, and the first feature may be "on" or "under" the second feature, and may include the first and second features being in direct contact, or may include the first and second features being not in direct contact but being in contact with another feature therebetween, and the first feature being "on", "above" and "above" the second feature may include the first feature being directly above and obliquely above the second feature, or merely indicating that the first feature is higher in level than the second feature.
A semi-active damper type uplift seismic isolation apparatus 100 according to an embodiment of the present invention will be described below with reference to the accompanying drawings.
Referring to fig. 1 and 2, a semi-active damper-type anti-plucking seismic isolation apparatus 100 according to an embodiment of the present invention may include: seismic isolation mount 13, mount tension and compression transducers 20, and at least one semi-active damper assembly 30.
Specifically, the support tension and compression sensor 20 is used to detect a stress state of the seismic isolation support 13, for example, it may detect that the seismic isolation support 13 is in a tension state or a non-tension state (e.g., a compression state).
The two ends of the vibration-isolating support 13 are respectively used for being connected with the upper building structure 400 and the lower building structure 500, so that the vibration-isolating support 13 can provide a vibration-isolating effect for the building structure. The ends of semi-active damper assembly 30 are also connected to upper building structure 400 and lower building structure 500, respectively, and semi-active damper assembly 30 is electrically connected to pedestal tension and compression sensor 20. Semi-active damper assembly 30 has a locked state in which semi-active damper assembly 30 cannot be extended and a retracted state in which semi-active damper assembly 30 is free to be extended and retracted.
In some embodiments, as shown in fig. 5 and 6, the upper building structure 400 may include an upper floor, an upper floor beam 200, and an upper pier 131, the upper end of the seismic isolation mount 13 may be connected to the upper pier 131, and the upper end of the semi-active damper assembly 30 may be connected to the upper floor beam 200 or the upper pier 131 (e.g., to an upper pre-buried plate 11 pre-buried in the upper pier 131); the lower building structure 500 may include a lower floor, a lower floor beam 300, and a lower pier 132, the lower end of the seismic mount 13 may be connected to the lower pier 132 (e.g., to a lower embedment plate 12 embedded in the lower pier 132), and the lower end of the semi-active damper assembly 30 may be connected to the lower floor beam 300 or the lower pier 132.
Further, the semi-active damper assembly 30 is configured to be switched to the locked state when the vibration-isolated mount 13 is in a pulled state, based on the detection result of the mount tension/compression sensor 20. In other words, when the vibration-isolating support 13 is pulled, the semi-active damper assembly 30 is switched to the non-telescopic state to ensure the overall anti-pulling performance and avoid the damage of the vibration-isolating support 13 due to the tensile force or the overlarge tensile force. Therefore, the semi-active damper type anti-pulling and shock-isolating device 100 can be used for anti-pulling and shock isolation of high-rise buildings and bear pulling force generated by the action of overturning force of the high-rise buildings.
When the semi-active damper assembly 30 is in a telescopic state, additional damping can be provided for horizontal shock isolation of the shock isolation support 13, and upper structure response of the shock isolation support 13 is reduced.
According to the semi-active damper type anti-pulling and shock-isolating device 100 provided by the embodiment of the utility model, the semi-active damper assembly 30 has the locking state and the telescopic state and is switched to the locking state when the shock-isolating support 13 is in the tension state, so that the semi-active damper type anti-pulling and shock-isolating device 100 is good in anti-pulling performance, the shock-isolating support 13 can be prevented from being damaged by tension, the anti-pulling and shock-isolating requirements of high-rise buildings with large height-width ratios can be met, the horizontal shock-isolating effect can be improved, and the upper structure response of the shock-isolating support 13 is reduced.
It should be noted that, in the embodiment of the present invention, the specific structure of the seismic isolation bearing 13 may be flexibly configured according to actual conditions, for example, the seismic isolation bearing 13 may be a rubber seismic isolation bearing, a friction pendulum seismic isolation bearing, an elastic sliding plate bearing, and the like, so as to ensure the horizontal seismic isolation performance of the semi-active damper type anti-pulling seismic isolation device 100.
As shown in fig. 1-2 and 5-6, the semi-active damper type anti-plucking seismic isolation apparatus 100 may further include: an upper embedment plate 11 and a lower embedment plate 12. The upper embedded plate 11 and the lower embedded plate 12 are distributed at intervals along the longitudinal direction, the upper embedded plate 11 is embedded in the upper building structure 400 to be fixed with the upper building structure 400, the lower embedded plate 12 is embedded in the lower building structure 500 to be fixed with the lower building structure 500, and the upper embedded plate 11 and the lower embedded plate 12 are respectively connected with two ends of the semi-active damper assembly 30 to provide a supporting point for the semi-active damper assembly 30, so that the semi-active damper assembly 30 is connected with the upper building structure 400 and the lower building structure 500, and the connecting structure is simple, firm and convenient.
Further, the upper embedded plate 11 and the lower embedded plate 12 are respectively located on both longitudinal sides (i.e., upper side and lower side) of the seismic isolation mount 13, for example, the upper building structure 400 includes an upper floor beam 200 and an upper buttress 131 for mounting the seismic isolation mount 13, the upper embedded plate 11 may be embedded in the upper buttress 131, the lower building structure 500 includes a lower floor beam 300 and a lower buttress 132 for mounting the seismic isolation mount 13, and the lower embedded plate 12 may be embedded in the lower buttress 132. Therefore, the vibration isolation support 13 and the semi-active damper assembly 30 are compact in structure, the semi-active damper assembly 30 improves the anti-pulling effect of the vibration isolation support 13 better, and the effect of preventing the vibration isolation support 13 from being damaged by tension is better.
It should be noted that, in the embodiment of the present invention, the upper embedded plate 11 may be a part which is independently designed and installed on the upper building structure 400, or the upper embedded plate 11 may be a part of the original upper building structure 400; it is within the scope of the present disclosure that the lower embedment plate 12 may be a separately designed and mounted component to the lower building structure 500, or that the lower embedment plate 12 may be a part of the original lower building structure 500.
It should be noted that, in the embodiment where the number of the semi-active damper assemblies 30 is multiple, multiple semi-active damper assemblies 30 may be connected to the same upper pre-buried plate 11 and the same lower pre-buried plate 12 as shown in fig. 1, or multiple semi-active damper assemblies 30 may be connected to multiple upper pre-buried plates 11 and multiple lower pre-buried plates 12, respectively, which is within the protection scope of the present invention.
According to some embodiments of the present invention, the support tension and compression sensor 20 may be disposed on at least one of the upper pre-embedded plate 11, the lower pre-embedded plate 12 and the vibration isolation support 13 to monitor the axial stress condition of the vibration isolation support 13.
In some embodiments, as shown in fig. 3, the support tension and compression sensor 20 is a distance sensor 21, such as a sliding plate contact sensor, a laser distance measurement sensor, etc., which is not affected by the horizontal movement of the seismic isolation support 13, so that the accuracy of vertical measurement and sensing is ensured. The distance sensor 21 is used for detecting the vertical height L of the seismic isolation support 13, for example, in some specific embodiments, since the distance between the seismic isolation support 13 and the upper pre-buried plate 11 and the lower pre-buried plate 12 is not changed, the distance sensor 21 may be installed on at least one of the upper pre-buried plate 11 and the lower pre-buried plate 12 to detect the distance between the upper pre-buried plate 11 and the lower pre-buried plate 12, and indirectly reflect the vertical height L of the seismic isolation support 13 according to the distance between the upper pre-buried plate 11 and the lower pre-buried plate 12; or the distance sensor 21 may be mounted to at least one of the upper pier 131 and the lower pier 132 to directly detect the vertical height L of the seismic mount 13. Specifically, when the vertical height L of the seismic isolation support 13 is greater than or equal to the preset distance L0, it indicates that the seismic isolation support 13 is in a tension state, and at this time, the semi-active damper assembly 30 needs to be switched to a locking state to avoid tension of the seismic isolation support 13. When the vertical height L of the vibration-isolating support 13 is smaller than the preset distance L0, it indicates that the vibration-isolating support 13 is in a pressed state or in a state of neither being pressed nor being pulled, and at this time, the semi-active damper assembly 30 can be switched to a telescopic state, and the semi-active damper assembly 30 can be freely telescopic so that the upper end and the lower end of the vibration-isolating support 13 can move relatively (for example, as shown in fig. 2), thereby ensuring the horizontal vibration-isolating performance of the vibration-isolating support 13.
In other embodiments, as shown in fig. 4, the support tension and compression sensor 20 is a stress sensor 22, and the stress sensor 22 is installed in the isolated support 13 to detect the axial stress of the isolated support 13, and the axial stress state of the isolated support 13 is used as a basis for determining whether the isolated support is pulled. Specifically, the isolated bearing 13 may be provided with a mounting hole, and the stress sensor 22 is disposed in the mounting hole, so that the stress sensor 22 can directly detect whether the axial stress state of the isolated bearing 13 is tensile stress or compressive stress, so that the semi-active damper assembly 30 is switched to a locked state when the isolated bearing 13 is tensile stress, and the semi-active damper assembly 30 is switched to a retractable state when the isolated bearing 13 is not stressed or stressed.
Of course, the form of the support tension and compression sensor 20 includes, but is not limited to, the distance sensor 21 and the stress sensor 22, and it is only required that the support tension and compression sensor 20 can directly detect the axial tension and compression stress state of the isolated support 13, or the axial tension and compression stress state of the isolated support 13 can be indirectly judged according to the detection result of the support tension and compression sensor 20.
The specific structure of the semi-active damper assembly 30 according to some embodiments of the present invention is described below with reference to the accompanying drawings.
According to some embodiments of the present invention, as shown in fig. 3 and 4, semi-active damper assembly 30 includes: cylinder 31, piston rod 32, piston 33, communicating tube 34 and control valve 35. The cylinder 31 has an oil chamber 311, and the oil chamber 311 may be filled with a damping fluid, such as a viscous damping fluid. A piston rod 32 is inserted through the cylinder 31, and a piston 33 is mounted to the piston rod 32 and located in the oil chamber 311 to divide the oil chamber 311 into a first chamber 312 and a second chamber 313. The communication pipe 34 is connected to the cylinder 31 and communicates the first chamber 312 and the second chamber 313. The control valve 35 is installed on the communication pipe 34, and the control valve 35 is electrically connected with the support pulling and pressing sensor 20 and is used for controlling the on-off of the communication pipe 34. The semi-active damper assembly 30 is simple in construction, convenient to manufacture, and has a large pull-out resistance.
Specifically, when the semi-active damper assembly 30 is in the locked state, the control valve 35 is closed, so that the damping fluid in the first chamber 312 and the second chamber 313 cannot circulate, and due to incompressibility of the fluid, the volumes of the first chamber 312 and the second chamber 313 are fixed, so that the piston 33 is locked in the fixed position and cannot move in the oil chamber 311, and the piston rod 32 is locked and can provide a pulling resistance force, thereby preventing the seismic isolation support 13 from bearing a pulling force.
When the semi-active damper assembly 30 is in the telescopic state, the control valve 35 is opened to allow the damping fluid in the first chamber 312 and the second chamber 313 to flow, and the volumes of the first chamber 312 and the second chamber 313 are variable, so that the piston 33 and the piston rod 32 can move relative to the oil cylinder 31, and the semi-active damper assembly 30 can freely extend and contract to provide additional damping for the seismic isolation bearing 13.
In some embodiments of the present invention, as shown with continued reference to fig. 3 and 4, the cylinder 31 further has an avoidance chamber 314, and the oil chamber 311 and the avoidance chamber 314 may be arranged generally in the up-down direction. A first end (e.g., an upper end) of the piston rod 32 is located outside the cylinder 31 and is connected to one of the upper building structure 400 and the lower building structure 500 (e.g., connected to one of the upper embedment plate 11 and the lower embedment plate 12), a second end (e.g., a lower end) of the piston rod 32 passes through the oil chamber 311 and extends into the avoidance chamber 314, and an end (e.g., a lower end) of the cylinder 31 remote from the first end of the piston rod 32 is connected to the other of the upper embedment plate beam 200 and the lower embedment plate beam 300 (e.g., connected to the other of the upper embedment plate 11 and the lower embedment plate 12). Therefore, the connection with the upper building structure 400 and the lower building structure 500 is realized, the avoidance cavity 314 avoids the piston rod 32 to ensure that the piston rod 32 has enough moving space, and the partition plates of the oil cavity 311 and the avoidance cavity 314 can also play a role in guiding the piston rod 32 to ensure that the piston rod 32 moves stably.
According to some embodiments of the present invention, as shown in fig. 1-6, the semi-active damper assembly 30 and the upper embedment plate 11 and the lower embedment plate 12 may be rotatably connected by a gimbal structure 37 to allow any angle of rotation between the semi-active damper assembly 30 and the upper embedment plate 11 and the lower embedment plate 12. On one hand, the semi-active damper type anti-pulling and shock-isolating device 100 can bear shearing force to play a role in damping and shock isolation, for example, as shown in fig. 1 and fig. 2, the upper end and the lower end of a shock-isolating support 13 generate relative motion in the horizontal direction, and the angle of the semi-active damper assembly 30 relative to the vertical direction is variable through the universal structure 37, so that the semi-active damper assembly 30 is stretched or compressed to provide additional damping; on the other hand, in the production design process, the semi-active damper assembly 30 can be matched with the seismic isolation support 13 at any height, so that the platform performance and the applicability of the semi-active damper assembly 30 are improved, and the cost is reduced.
The universal structure 37 is not limited in particular, and the universal structure 37 may be a universal joint or a ball joint, for example. For example, in the example shown in fig. 1-6, the universal structure 37 is a spherical hinge, the two ends (e.g., the upper end of the piston rod 32 and the lower end of the cylinder 31) of the semi-active damper assembly 30 are respectively provided with a spherical body 36, the upper pre-embedded plate 11 and the lower pre-embedded plate 12 are respectively provided with a spherical shell, and the spherical body 36 and the spherical shell cooperate to form the spherical hinge.
According to some embodiments of the present invention, as shown in fig. 1-2 and 5-6, the number of semi-active damper assemblies 30 is greater than or equal to three, and at least three semi-active damper assemblies 30 extend upwardly toward or away from each other. When the semi-active damper assembly 30 is in the locked state, the entire semi-active damper type anti-pulling seismic isolation device 100 can be completely locked.
Taking four semi-active damper assemblies 30 as an example, if the four semi-active damper assemblies 30 extend in the same direction, the four semi-active damper assemblies 30 can be rotated to produce vertical height changes even though the semi-active damper assemblies 30 are in a locked state because the semi-active damper assemblies 30 are rotatably coupled (e.g., coupled via the gimbal structure 37) to the upper building structure 400 and the lower building structure 500. If the semi-active damper type anti-pulling seismic isolation apparatus 100 has moved horizontally before the tensile force is generated, i.e. the four semi-active damper assemblies 30 have all rotated to extend vertically, the semi-active damper assemblies will rotate reversely to extend vertically when receiving the tensile force, thereby affecting the anti-pulling effect.
Through the upwards extension of being close to each other or keeping away from each other of at least three semi-active damper subassembly 30, make whole arrangement be the terrace with edge form or chamfered platform form, can guarantee to lock totally when semi-active damper subassembly 30 locks, and do not take place to rotate and influence resistance to plucking antidetonation effect.
In some embodiments, as shown in fig. 1 and 2, the seismic isolation bearing 13 is disposed in cooperation with (i.e., adjacent to) a plurality of semi-active damper assemblies 30, and the plurality of semi-active damper assemblies 30 are distributed at intervals along the circumferential direction of the seismic isolation bearing 13, so that a single seismic isolation bearing 13 can have a good anti-pulling seismic isolation effect.
In other embodiments, as shown in fig. 7 and 8, the semi-active damper-type anti-pluck isolation apparatus 100 may include a plurality of isolation mounts 13 to achieve a multi-point arrangement of the semi-active damper-type anti-pluck isolation apparatus 100 in the building structure. Each vibration isolation support 13 is matched with at least one semi-active damper assembly 30 (namely, adjacent to the vibration isolation support), reliable anti-pulling vibration isolation effects can be achieved through the matching of the plurality of semi-active damper assemblies 30 matched with the plurality of vibration isolation supports 13 respectively, the number of the semi-active damper assemblies 30 arranged adjacent to each vibration isolation support 13 can be small (for example, one or two), and the vibration isolation supports 13 and the corresponding semi-active damper assemblies 30 can meet the installation requirements of special positions of a building, for example, the vibration isolation supports are installed at corner positions of the building.
According to some embodiments of the present invention, as shown in fig. 1-2 and 5-8, the projections of the at least two semi-active damper assemblies 30 along a first vertical plane are not parallel to each other, and the projections of the at least two semi-active damper assemblies 30 along a second vertical plane are not parallel to each other, wherein the first vertical plane and the second vertical plane intersect, e.g., the first vertical plane is an east-west plane and the second vertical plane is a north-south plane. Thereby, the entire device can be locked in the intersecting vertical planes.
It should be noted that the "first vertical surface" and the "second vertical surface" are any two planes extending in the vertical direction. The "at least two semi-active damper assemblies 30" may be the semi-active damper assemblies 30 arranged in cooperation with the same isolation bearing 13 assembly, or may be the semi-active damper assemblies 30 arranged in cooperation with different isolation bearing 13 assemblies respectively.
For example, in the specific example shown in fig. 1 and 2, each seismic isolation support 13 is matched with four semi-active damper assemblies 30, and the four semi-active damper assemblies 30 are in the edge shape of a prismatic table or an inverted frustum when the seismic isolation support 13 is in the original point state (i.e., in the state where no deformation occurs in the horizontal direction or the vertical direction), so that the semi-active damper type anti-pulling seismic isolation device 100 can play a seismic isolation role in multiple directions, and the horizontal seismic isolation and anti-pulling seismic isolation effects are improved.
For example, in the specific example shown in fig. 7 and 8, there are four seismic isolation supports 13, each seismic isolation support 13 is matched with one semi-active damper assembly 30, the seismic isolation support 13 is in the original point state, the four semi-active damper assemblies 30 are in the shape of an edge of a frustum of a pyramid, the central lines of the four semi-active damper assemblies 30 are projected as two intersecting lines on the vertical plane along the left-right direction, and the central lines of the four semi-active damper assemblies 30 are projected as two intersecting lines on the vertical plane along the front-back direction, so that the four semi-active damper assemblies 30 are matched with the building structure when being in the locking state, and the semi-active damper type anti-pulling seismic isolation device 100 can be completely locked.
Herein, "front", "rear", "left", "right", etc. orientations are based on the orientation shown in the figures, are only for convenience in describing the present invention and to simplify the description, and do not indicate or imply that semi-active damper assembly 30 has a particular orientation, is constructed and operates in a particular orientation, and thus is not to be construed as limiting the utility model.
The following describes a performance design of the semi-active damper type anti-plucking seismic isolation apparatus 100 according to an embodiment of the present invention with reference to the accompanying drawings.
Assuming that the design anti-pulling force of the semi-active damper type anti-pulling seismic isolation device 100 is T, there are n semi-active damper assemblies 30 and the ith semi-active damper assembly 30The maximum pullout resistance of FiConsidering the influence of the included angle between the semi-active damper assemblies 30, the included angle between the semi-active damper assembly 30 and the vertical direction is θ when the semi-active damper type anti-pulling seismic isolation device 100 is assumed to have maximum displacementiThen, the semi-active damper type anti-pulling vibration isolation apparatus 100 is designed to have an anti-pulling force satisfying the formula (1).
When the vibration-isolating support 13 is at the original point, the relative speed of the upper structure of the vibration-isolating support 13 relative to the lower structure is usually at the maximum value, and the minimum damping coefficient in the motion of the semi-active damper type anti-pulling vibration-isolating device 100 at the point, namely the damping coefficient of the whole device when the vibration-isolating support 13 moves along the diagonal direction (as shown in fig. 2), is used as the design damping coefficient of the semi-active damper type anti-pulling vibration-isolating device 100. Only the semi-active damper assembly 30 disposed along this diagonal provides the damping force at this time. In view of symmetry, assume that semi-active damper assembly 30 is at an angle to the horizontal when isolation bearing 13 is at the originDamping coefficient of a single semi-active damper assembly 30 is c0If the damping fluid damping index in the semi-active damper assembly 30 is α, the designed damping coefficient c of the entire device satisfies equation (2).
Assuming that the relative velocity v of the upper structure of the seismic isolation mount 13 with respect to the lower structure, the design damping force F of the semi-active damper-type anti-plucking seismic isolation apparatus 100 satisfies equation (3).
F=cvα…………………………………………(3)
Therefore, by arranging the semi-active damper assembly 30, a reliable anti-pulling effect can be guaranteed, the shock insulation support 13 is prevented from being damaged by tension, additional damping can be provided for the shock insulation support 13 when the shock insulation support is pressed, the horizontal shock insulation effect is improved, and the anti-pulling shock insulation and horizontal shock insulation effects of the whole semi-active damper type anti-pulling shock insulation device 100 are obviously improved.
Other constructions and operations of the semi-active damper-type anti-plucking vibration isolation apparatus 100 according to the embodiment of the present invention are known to those skilled in the art and will not be described in detail herein.
In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.
In the description herein, references to the description of the terms "embodiment," "particular embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.
While embodiments of the utility model have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the claims and their equivalents.
Claims (10)
1. The utility model provides a semi-active damper formula resistance to plucking isolation device which characterized in that includes:
the two ends of the shock insulation support are respectively suitable for being connected with an upper building structure and a lower building structure;
the support pulling and pressing sensor is used for detecting the stress state of the shock insulation support;
at least one semi-active damper assembly having two ends adapted to be connected to the upper building structure and the lower building structure, respectively, and electrically connected to the pedestal tension and compression sensor, wherein,
the semi-active damper assembly has a locked state and a retractable state, and is configured to switch to the locked state when the isolation bearing is in tension.
2. The semi-active damper, anti-plucking seismic isolation apparatus as claimed in claim 1, wherein said semi-active damper assembly comprises:
an oil cylinder having an oil cavity;
the piston rod penetrates through the oil cylinder;
a piston mounted to the piston rod and located within the oil chamber to divide the oil chamber into a first chamber and a second chamber;
the communicating pipe is connected with the oil cylinder and communicates the first chamber and the second chamber;
a control valve installed on the communication pipe and used for controlling the on-off of the communication pipe, the control valve is electrically connected with the support pull and press sensor, wherein,
the semi-active damper assembly is in the locked state, the control valve is closed; the semi-active damper assembly is in the retractable state, the control valve is open.
3. The semi-active damper type anti-plucking seismic isolation device as claimed in claim 2, wherein said cylinder further has an escape cavity, a first end of said piston rod is located outside said cylinder and connected to one of said upper building structure and said lower building structure, a second end of said piston rod passes through said oil chamber and extends into said escape cavity, and an end of said cylinder remote from said first end of said piston rod is connected to the other of said upper building structure and said lower building structure.
4. The semi-active damper type anti-plucking seismic isolation apparatus as claimed in claim 1, further comprising:
an upper pre-embedded plate and a lower pre-embedded plate, which are pre-embedded in the upper building structure and the building structure respectively and connected with two ends of the semi-active damper assembly respectively,
the upper embedded plate and the lower embedded plate are respectively positioned at two longitudinal sides of the shock insulation support.
5. The semi-active damper type anti-plucking seismic isolation apparatus as claimed in claim 4, wherein said semi-active damper assembly is rotatably connected to said upper pre-buried plate and said lower pre-buried plate by a universal structure.
6. The semi-active damper type anti-plucking seismic isolation apparatus as claimed in claim 1,
the support pulling and pressing sensor is a distance sensor used for detecting the longitudinal height of the shock insulation support, wherein,
and when the vertical height of the shock insulation support is greater than or equal to the preset interval, the shock insulation support is in the tensioned state.
7. The semi-active damper type anti-plucking seismic isolation apparatus as claimed in claim 1,
the support tension and compression sensor is a stress sensor, and the stress sensor is installed in the shock insulation support.
8. The semi-active damper, uplift isolation device according to any one of claims 1-7, wherein the number of semi-active damper assemblies is greater than or equal to three, at least three of the semi-active damper assemblies being upwardly close to each other or extending away from each other.
9. The semi-active damper type anti-plucking seismic isolation apparatus as claimed in claim 8,
the semi-active damper assemblies are distributed at intervals along the circumferential direction of the vibration isolation support; or the number of the shock insulation supports is multiple, and each shock insulation support is arranged corresponding to at least one semi-active damper assembly.
10. The semi-active damper, anti-plucking seismic isolation apparatus of claim 8, wherein at least two of said semi-active damper assemblies are non-parallel to each other in projection along a first vertical plane and at least two of said semi-active damper assemblies are non-parallel to each other in projection along a second vertical plane, wherein,
the first vertical surface and the second vertical surface intersect.
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