CN212000603U

CN212000603U - Vibration isolation device with adjustable vertical rigidity

Info

Publication number: CN212000603U
Application number: CN201922491289.2U
Authority: CN
Inventors: 孙亮明; 廖亚凡; 胡振; 汪琳紫; 毋双
Original assignee: Wuhan University of Technology WUT
Current assignee: Wuhan University of Technology WUT
Priority date: 2019-12-31
Filing date: 2019-12-31
Publication date: 2020-11-24
Anticipated expiration: 2029-12-31

Abstract

The utility model provides a vertical rigidity adjustable vibration isolation device, which solves the technical problem that the vertical rigidity of the vibration isolation device in the prior art can not be adjusted; the shear force tenon type vibration isolation device comprises a bottom plate, a top plate, a shear force tenon, at least three rubber vibration isolation components and at least three adjustable spring supports, wherein the top plate is positioned above the bottom plate and is arranged opposite to the bottom plate at intervals; each adjustable spring support comprises an upper base plate, a lower base plate, a steel spring, a connecting column, a sleeve and a fastener, wherein the upper base plate is fixedly connected to the top plate, the lower base plate is fixedly connected to the bottom plate, the connecting column is vertically fixed to the lower base plate, the lower end of the steel spring is sleeved on the connecting column and is fixedly connected with the lower end of the connecting column, the outer wall of the connecting column is sleeved with the sleeve in an adjustable sliding mode, a part of the steel spring corresponding to the sleeve is fixed to the connecting column, the vertical rigidity between the bottom plate and the top plate is adjusted, and.

Description

Vibration isolation device with adjustable vertical rigidity

Technical Field

The utility model relates to a vibration control technical field, concretely relates to vibration isolation mounting with adjustable vertical rigidity.

Background

With the rapid development of urban construction, urban rail and road traffic networks are developed more and more, ground traffic is saturated day by day, and three-dimensional traffic combining underground traffic and elevated traffic is increased day by day, so that great convenience is brought to people going out. However, most of the traffic lines are close to or even pass through dense residential areas, commercial areas, cultural and educational areas, high-tech industrial parks and the like in cities, and increasingly busy traffic lines can induce long-term environmental vibration pollution, which seriously affects normal work and life of people along the lines and normal use of precision instruments and equipment in sensitive buildings. How to prevent and treat the vehicle-induced environmental vibration becomes a practical problem which has to be solved for constructing an environment-friendly society in engineering construction.

Practice proves that the influence of vibration induced by vehicle running on the environment is mainly vertical vibration, the influence of earthquake action on the structure safety is mainly horizontal vibration, and plastic deformation of the structure and the auxiliary structures thereof can be caused, so that a weak vibration control method is different from a strong vibration control method, and the adaptability of the vibration isolation support needs to be considered. The existing rubber support focuses on the horizontal shock insulation function and does not consider the vertical shock absorption function. The vibration isolation support is an effective vibration control measure, can be used as a propagation path measure to reduce the propagation of vehicle-induced vibration of an elevated bridge to the surrounding environment, and can also be used as a vibration receiving measure to reduce the propagation of vehicle-induced vibration to a sensitive building. In order to exert the vertical vibration reduction effect of the vibration isolation support to the maximum extent, the vibration isolation support is required to have the characteristics of low vertical rigidity and high damping as far as possible, the vibration dominant frequency band of the structure is changed, the resonance phenomenon of the structure is further avoided, and otherwise the vibration reduction effect of the vibration isolation support is greatly reduced.

Due to the fact that the actual natural frequency of the structure deviates from the design value, and due to the fact that external factors such as auxiliary facilities and construction errors are arranged in the later stage of a part of the structure, specific parameters of the structure are prone to change, and therefore it is required that the natural frequency of the vibration isolation support can be adjusted correspondingly at any time. However, the natural frequency of the existing vibration isolation support including a rubber support or a spring support is always a fixed value and cannot be adjusted, the natural frequency is adjusted mainly by replacing the support model, great waste of materials and manpower is caused, the construction difficulty is high, accurate adjustment is difficult to achieve, and different vibration reduction and isolation requirements are difficult to adapt. Therefore, higher requirements are provided for vibration reduction and isolation of viaducts, sensitive buildings and the like in urban construction, and the technical requirement for developing a vibration isolation support with adjustable vertical rigidity to achieve reasonable and effective vibration reduction and isolation effects exists in the field.

SUMMERY OF THE UTILITY MODEL

The utility model provides a vibration isolation mounting with adjustable vertical rigidity to solve among the prior art technical problem that vibration isolation mounting can't realize that vertical rigidity is adjustable.

The utility model provides a scheme as follows of above-mentioned technical problem: a vertical stiffness adjustable vibration isolation device comprises a bottom plate, a top plate, a shear force clamping tenon, at least three rubber vibration isolation components and at least three adjustable spring supports, wherein the top plate is positioned above the bottom plate and is arranged opposite to the bottom plate at intervals; each spring bracket with adjustable include top base plate, infrabasal plate, steel spring, spliced pole, sleeve and fastener, top base plate fixed connection in the roof, infrabasal plate fixed connection in the bottom plate, the spliced pole is vertical to be fixed in the infrabasal plate, the lower pot head of steel spring is located the spliced pole, and with the lower extreme fixed connection of spliced pole, the slip cap that the sleeve is adjustable is located the spliced pole outer wall, be used for with the sleeve corresponds the partial steel spring of position and is fixed in the spliced pole, in order to adjust the bottom plate with vertical rigidity between the roof, the fastener is used for fixing the sleeve is in relative position on the spliced pole.

The utility model provides an isolation mounting with adjustable vertical rigidity, steel spring's lower pot head is located the spliced pole, and with the lower extreme fixed connection of spliced pole, steel spring's upper end with roof fixed connection, when the sleeve upwards or during the lapse in succession on the spliced pole, because the sleeve can be fixed in the spliced pole with the part steel spring that corresponds the position on, just can make steel spring's effective length change in succession, and then can be in the vertical rigidity of continuous adjustment adjustable spring bracket in the certain limit to make vertical rigidity between bottom plate and the roof change, solved among the prior art isolation (shake) support can't realize vertical rigidity continuous adjustable technical problem.

The above description is only an overview of the technical solution of the present invention, and in order to make the technical means of the present invention clearer and can be implemented according to the content of the description, the following detailed description is made with reference to the preferred embodiments of the present invention and accompanying drawings. The detailed description of the present invention is given by the following examples and the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without undue limitation to the invention. In the drawings:

fig. 1 is a schematic view of a three-dimensional structure of a vertical stiffness adjustable vibration isolation device according to an embodiment of the present invention after a top plate is hidden;

fig. 2 is a schematic perspective view of a vertical stiffness adjustable vibration isolation device according to an embodiment of the present invention;

fig. 3 is a schematic view of a longitudinal cross section of a vertical stiffness adjustable vibration isolation device according to an embodiment of the present invention.

Detailed Description

The principles and features of the present invention are described below in conjunction with the following drawings, the examples given are only intended to illustrate the present invention and are not intended to limit the scope of the present invention. The invention is described in more detail in the following paragraphs by way of example with reference to the accompanying drawings. The advantages and features of the present invention will become more fully apparent from the following description and appended claims. It should be noted that the drawings are in simplified form and are not to precise scale, and are provided for convenience and clarity in order to facilitate the description of the embodiments of the present invention.

As shown in fig. 1 and 2, the utility model provides an isolation mounting with adjustable vertical rigidity, including bottom plate 1, roof 2, shear force tenon 3 and at least three rubber isolation subassembly 4 and at least three adjustable spring bracket 5, in this implementation, the number of rubber isolation subassembly is 4, and the number of adjustable spring bracket is 4.

It should be noted that, realize the utility model discloses in technical scheme, rubber vibration isolation subassembly and adjustable spring bracket several only need 4 can, this embodiment is only the utility model relates to an embodiment of preferred, the number of rubber vibration isolation subassembly and adjustable spring bracket can also be for other figure in other embodiments.

The top plate 2 is positioned above the bottom plate 1 and is opposite to the bottom plate 1 at an interval; the bottom plate 1 is used as a supporting base body of the whole vibration isolation device, the top plate 2 is used as a carrier of a building or a vehicle above the vibration isolation device, the bottom plate and the top plate are arranged at intervals, and a vibration isolation cavity for isolating vibration is formed in the middle of the top plate and the top plate.

As shown in fig. 1 and 3, the lower end of the shear tenon 3 is fixed to the bottom plate 1, and the upper end is elastically connected to the top plate 2; specifically, the shear latch 3 includes a steel bar 31, a soft sleeve 32, and an elastic member 33, wherein the lower end of the steel bar 31 is fixedly mounted on the bottom plate 1, the soft sleeve 32 is elastically connected to the top plate 2 through the elastic member 33, a slot 32a is formed at the lower end of the soft sleeve 32, the upper end of the steel bar 31 is inserted into the slot 32a, the soft sleeve 32 is preferably a rubber sleeve or a plastic sleeve, and the elastic member 33 is preferably a spring or an elastic telescopic rod.

The shear tenon 3 is used as a main supporting mechanism between the bottom plate 1 and the top plate 2, and the steel bar 31 can limit the excessive horizontal displacement of the top plate 2, so that the safety of the upper structure is ensured.

The rubber vibration isolation assembly 4 comprises an upper connecting block 41, an inclined rubber combined block 42 and a lower connecting block 43, and when a large horizontal displacement occurs, the soft sleeve 32 can effectively prevent the shear tenon 7 from contacting with the upper connecting block 41 to isolate vibration transmission.

Specifically, the upper connecting block 41 is fixedly mounted on the top plate 2, the lower connecting block 43 is fixedly mounted on the bottom plate 1, the upper connecting block 41 and the corresponding lower connecting block 43 are arranged oppositely, the inclined rubber combined blocks 42 are fixedly arranged between the upper connecting block 41 and the corresponding lower connecting block 43, the inclined rubber combined blocks 42 are located on the outer side of the shear tenon 3, and according to the three-point surface forming principle, the horizontal projections of all the rubber vibration isolation components 4 are not on the same straight line.

The lower end of the upper connection block 41 is provided with a first inclined surface 412, the upper end of the lower connection block 43 is provided with a second inclined surface 432, the first inclined surface 412 and the corresponding second inclined surface 432 are oppositely arranged, and the inclined rubber combination block 42 is arranged between the first inclined surface 412 and the corresponding second inclined surface 432.

In this embodiment, the inclined rubber combination block 42 includes an upper sealing plate 421, a lower sealing plate 424, a plurality of rubber layers 423 and a plurality of steel plate layers 422, the upper end of the upper sealing plate 421 is connected to the first inclined surface 412, the lower end of the lower sealing plate 424 is connected to the second inclined surface 432, and the plurality of rubber layers 423 and the plurality of steel plate layers 422 are sequentially stacked between the upper sealing plate 421 and the lower sealing plate 424 at intervals.

The rubber layer 423 and the steel plate layer 422 can be inlaid, bonded and vulcanized in actual production, and the outer layer of the inclined rubber combination block 42 is wrapped with the rubber protection layer 44.

The four rubber vibration isolation components 4 are uniformly distributed at intervals along the circumferential direction of the shear tenon 3, and the four inclined rubber combination blocks 42 are obliquely arranged along the shear tenon 3, and one side close to the shear tenon 3 is low, and the other side is high.

The inclined rubber combination blocks 42 can provide certain horizontal rigidity and vertical rigidity, realize effective frequency shift and energy consumption functions, can meet vibration reduction and isolation requirements of different working conditions, and have a certain three-way vibration isolation/shock function.

In practical use, the inclination angle of the inclined rubber combination block 42 can be determined according to practical conditions, and the inclined rubber combination block 42 can have good three-way vibration isolation/shock absorption effect within an angle interval of 10-60 degrees.

Wherein each adjustable spring support 5 comprises a steel spring 51, a connecting post 52, a sleeve 53 and a fastener 54.

Specifically, the connecting column 52 is vertically fixed on the bottom plate 1, the lower end of the steel spring 51 is sleeved on the connecting column 52 and is fixedly connected with the lower end of the connecting column 52, the upper end of the steel spring 51 is fixedly connected with the top plate 2, the sleeve 53 is slidably sleeved on the outer wall of the connecting column 52 in an adjustable manner and is used for fixing part of the steel spring 51 corresponding to the sleeve 53 on the connecting column 52 so as to adjust the vertical rigidity between the bottom plate 1 and the top plate 2, the fastener 54 is used for fixing the relative position of the sleeve 53 on the connecting column 52, and according to the three-point surface forming principle, the horizontal projections of the four adjustable spring supports 5 are not in the same straight line.

In practical use and installation, in order to facilitate the fixing of the steel spring, the lower end of the connecting column 52 is provided with a lower base plate 55, the upper end of the steel spring 51 is provided with an upper base plate 56, wherein the upper base plate 56 is fixedly connected with the top plate 2, and the lower base plate 55 is fixedly connected with the bottom plate 1.

In this embodiment, a first spiral groove is formed on an outer side wall of the connection post 52, a second spiral groove is formed on an inner side wall of the sleeve 53, the steel spring 51 is wound and ascended along the first spiral groove, the second spiral groove is engaged with an outer side wall of the steel spring 51, and the fastening member 54 is a set screw passing through the side wall of the sleeve.

The four adjustable spring supports 5 are uniformly distributed at intervals along the circumferential direction of the shear tenon 3 and are distributed on two sides of the rubber vibration isolation component 4.

The steel spring 51 on the inner wall of the sleeve 53 is rendered ineffective by the sleeve 53 gripping the inner wall of the sleeve 53 and a part of the outer wall of the connecting post 52, i.e. the effective length of the steel spring 51 is substantially only the part above the sleeve 53.

By rotating the sleeve upwards or downwards, the effective length of the steel spring is changed, so that the continuous adjustment of the effective vertical stiffness of the adjustable spring support 5 can be realized within a certain range, the natural vibration frequency of the vibration isolation device is further adjusted, and the vertical vibration dominant frequency band of the actual structure is changed. The vertical stiffness of the vibration isolation device is changed when the relative position of the sleeve 53 on the connection post 52 is changed.

Wherein the adjustable interval of the vertical stiffness of the adjustable spring support can be determined in such a way that the total stiffness of each steel spring is assumed to be k_sTotal length of L_mWherein the maximum length of the steel spring embedded in the sleeve is L_sTherefore, the adjustable interval of the vertical stiffness of each steel spring is:

during actual use, the effective vertical stiffness of the spring system can be continuously adjusted within a certain range by changing the effective length of the steel spring 51 according to the actual engineering situation, so that the natural vibration frequency of the vibration isolation support is adjusted, the vertical vibration dominant frequency band of the actual structure is changed, and the optimal vertical vibration isolation effect is realized.

Compared with the prior art, the embodiment of the utility model provides a following technological effect has at least:

1. the inclined rubber combination block adopted by the rubber vibration isolation assembly has the characteristics of low rigidity and high damping, and can provide certain horizontal rigidity and vertical rigidity by designing the size of the inclination angle of the rubber combination block according to the design condition of the upper structure of the vibration isolation device, so that the effective frequency shift and energy consumption effects are realized, and a certain three-way vibration isolation/vibration isolation effect is formed according to vibration reduction and isolation requirements of different working conditions.

2. The adjustable spring support can continuously adjust the vertical stiffness of the adjustable spring support within a certain range by changing the effective length of the steel spring according to the actual engineering situation, and further adjust the natural vibration frequency of the vibration isolation device, so that the vertical vibration dominant frequency band of the actual structure is changed, and the optimal vertical vibration isolation effect is realized.

3. The utility model discloses vibration isolation device has adopted three and above slope rubber combination piece to evenly arrange along shear force tenon circumference, both can provide vertical rigidity for superstructure, can provide sufficient horizontal rigidity again, its vertical rigidity can guarantee the bearing capacity to superstructure, its level can restrict superstructure's horizontal displacement in order to guarantee superstructure's safety to rigidity, play fixed superstructure's effect, especially to urban overhead rail transit, vertical rigidity can reduce the bridge amount of deflection under the train load effect, guarantee the security and the stationarity of train operation, train brake can be guaranteed to its horizontal rigidity, the extra horizontal load that produces in the operation processes such as high-speed bending can not cause the horizontal displacement on a large scale of the overpass roof beam body, ensure circuit operation safety.

4. The shear force tenon can limit overlarge horizontal displacement of the upper structure, and the safety of the upper structure of the vibration isolation device is guaranteed.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way; the present invention can be smoothly implemented by those skilled in the art according to the drawings and the above description; however, those skilled in the art should understand that changes, modifications and variations made by the above-described technology can be made without departing from the scope of the present invention, and all such changes, modifications and variations are equivalent embodiments of the present invention; meanwhile, any changes, modifications, evolutions, etc. of the above embodiments, which are equivalent to the actual techniques of the present invention, still belong to the protection scope of the technical solution of the present invention.

Claims

1. The vibration isolation device with the adjustable vertical stiffness is characterized by comprising a bottom plate, a top plate, a shear force tenon, at least three rubber vibration isolation components and at least three adjustable spring supports, wherein the top plate is positioned above the bottom plate and is arranged opposite to the bottom plate at intervals; each spring bracket with adjustable include steel spring, spliced pole, sleeve and fastener, the spliced pole is vertical to be fixed in the bottom plate, the lower pot head of steel spring is located the spliced pole, and with the lower extreme fixed connection of spliced pole, the upper end of steel spring with roof fixed connection, the slip cap with adjustable sleeve is located the spliced pole outer wall, be used for with the part steel spring that the sleeve corresponds the position is fixed in the spliced pole, in order to adjust the bottom plate with vertical rigidity between the roof, the fastener is used for fixing the sleeve is in relative position on the spliced pole, all the horizontal projection of spring bracket with adjustable is not in on the same straight line.

2. The adjustable vertical stiffness vibration isolator as claimed in claim 1, wherein each of the rubber vibration isolating assemblies includes an upper connection block, an inclined rubber combination block, and a lower connection block; the upper connecting blocks are fixedly arranged on the top plate, the lower connecting blocks are fixedly arranged on the bottom plate, the upper connecting blocks and the corresponding lower connecting blocks are arranged oppositely, the inclined rubber combination blocks are fixedly arranged between the upper connecting blocks and the corresponding lower connecting blocks, and the horizontal projections of all the rubber vibration isolation components are not in the same straight line.

3. The vibration isolation device with adjustable vertical stiffness according to claim 2, wherein a first spiral groove is formed on an outer side wall of the connecting column, a second spiral groove is formed on an inner side wall of the sleeve, the steel spring is coiled and ascended along the first spiral groove, the second spiral groove is embedded with an outer side wall of the steel spring, and the fastening member is a set screw penetrating through a side wall of the sleeve to prevent the sleeve from sliding down.

4. The adjustable vertical stiffness vibration isolator as claimed in claim 1, wherein all of the rubber vibration isolation assemblies are evenly spaced along the circumference of the shear tenon.

5. The adjustable vertical stiffness vibration isolator as claimed in claim 4, wherein all of the adjustable spring mounts are spaced evenly along the circumference of the shear tenon and are located on both sides of the rubber vibration isolator assembly.

6. The adjustable vertical stiffness vibration isolator as claimed in claim 2, wherein a lower end of the upper connection block is configured as a first inclined surface, an upper end of the lower connection block is configured as a second inclined surface, the first inclined surface and the corresponding second inclined surface are oppositely disposed, and the inclined rubber combination block is disposed between the first inclined surface and the corresponding second inclined surface.

7. The vibration isolation device with adjustable vertical rigidity according to claim 2, wherein the inclined angle of the inclined rubber combination block is 10-60 °, and the height of one side of the inclined rubber combination block close to the shear tenon is lower than that of the other side.

8. The vibration isolation device with adjustable vertical rigidity according to claim 6, wherein the inclined rubber composite block comprises an upper sealing plate, a lower sealing plate, a rubber layer and a steel plate layer, the upper end of the upper sealing plate is connected to the first inclined surface, the lower end of the lower sealing plate is connected to the second inclined surface, and a plurality of the rubber layers and a plurality of the steel plate layers are sequentially stacked between the upper sealing plate and the lower sealing plate at intervals.

9. The vibration isolation device with adjustable vertical rigidity according to claim 4, wherein the shear latch comprises a steel bar, a soft sleeve and an elastic member, the lower end of the steel bar is fixedly installed on the bottom plate, the soft sleeve is elastically connected with the top plate through the elastic member, a slot is formed at the lower end of the soft sleeve, and the upper end of the steel bar is inserted into the slot.