HIGH-PRESSURE BEARABLE SCALE TYPE BRIDGE RUBBER BEARING

Abstract

The present invention provides a high-pressure bearable scale type bridge rubber bearing, comprising spring rubber vibration reduction pad assemblies, a flexible steel plate assembly and a rubber bearing body. The rubber bearing body comprises an outer rubber portion and an inner rubber portion; the outer rubber portion is wrapped around the outside of the spring rubber vibration reduction pad assemblies and the flexible steel plate assembly; the spring rubber vibration reduction pad assemblies are arranged on the upper side and the lower side of the inner rubber portion; and the flexible steel plate assembly is fixedly mounted between the spring rubber vibration reduction pad assemblies. The rubber bearing of the present invention has a relatively large elastic deformation after being loaded and can effectively conduct vibration reduction and earthquake resistance during use.

Claims

1. A high-pressure bearable scale type bridge rubber bearing, comprising spring rubber vibration reduction pad assemblies, a flexible steel plate assembly and a rubber bearing body, wherein the rubber bearing body comprises an outer rubber portion and an inner rubber portion; the outer rubber portion is wrapped around the outside of the spring rubber vibration reduction pad assemblies and the flexible steel plate assembly; the spring rubber vibration reduction pad assemblies are arranged on the upper side and the lower side of the inner rubber portion; the flexible steel plate assembly is fixedly mounted between the spring rubber vibration reduction pad assemblies; and spring rubber vibration reduction assemblies and the flexible steel plate assembly are wrapped around the inner rubber portion.

2. The high-pressure bearable scale type bridge rubber bearing according to claim 1, wherein the flexible steel plate assembly comprises a plurality of arch-shaped flexible steel plates; the arch-shaped flexible steel plates are mutually combined and spliced in a successive lap joint manner to form a cylindrical structure with a waist sunken; and the inner rubber portion is arranged in the cylindrical structure.

3. The high-pressure bearable scale type bridge rubber bearing according to claim 2, wherein a zigzag type splicing opening is formed between adjacent arch-shaped flexible steel plates; and in a cross section, an upper steel plate of each arch-shaped flexible steel plate is successively in lap joint to a lower steel plate of the arch-shaped flexible steel plate before.

4. The high-pressure bearable scale type bridge rubber bearing according to claim 1, wherein the outer side surface of the outer rubber portion is a sunken arch-shaped curved surface.

5. The high-pressure bearable scale type bridge rubber bearing according to claim 1, wherein each spring rubber vibration reduction pad assembly comprises an upper steel plate layer, a lower steel plate layer, fixing bolts, springs and fixed columns; a plurality of fixed columns axe fixedly arranged on the upper surface of the lower steel plate layer at uniform intervals; threaded holes are formed in the fixed columns; through holes are formed in the upper steel plate layer; the upper steel plate layer is fixed to the fixed columns by the fixing bolts penetrating through the through holes; and the springs are sleeved at the peripheries of the fixed columns.

6. The high-pressure bearable scale type bridge rubber bearing according to claim 5, wherein the fixed columns are specifically arranged in a circular array; and heights of the springs sleeved outside the fixed columns are identically set.

7. The high-pressure bearable scale type bridge rubber bearing according to claim 5, wherein a gasket is arranged between each fixing boll and the upper surface of the upper steel plate layer.

8. The high-pressure bearable scale type bridge rubber bearing according to claim 5, wherein the fixed column is of an eccentric elliptic platform shaped structure; and an ellipse on the bottom surface, an ellipse on the top surface and the side surface of an eccentric elliptic platform form a symmetric key shaped body.

9. The high-pressure bearable scale type bridge rubber bearing according to claim 8, wherein a length of a long axis of the ellipse on the bottom surface of the fixed column is consistent to a radius of the spring.

10. The high-pressure bearable scale type bridge rubber bearing according to claim 5, wherein each fixed column is made of rubber with viscoelasticity, weak hardness and high damping.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0029] FIG. 1 is a schematic diagram of a structure of a bridge rubber bearing.

[0030] FIG. 2 is a cross-sectional view of splicing of a combined flexible steel plate.

[0031] FIG. 3 is a schematic diagram of a structure of a spring rubber vibration reduction pad assembly.

[0032] FIG. 4 is a diagram showing a detail regarding a construction of a fixed column.

[0033] FIG. 5 is a diagram showing a detail regarding a bolt.

[0034] Description of reference numerals: spring rubber vibration reduction pad assembly 1, upper steel plate layer 11, lower steel plate layer 12, fixing bolt 13, spring 14, fixed column 15, threaded hole 151, flexible steel plate assembly 2, arch-shaped flexible steel plate 21, splicing opening 22, rubber bearing body 3, outer rubber portion 31, inner rubber portion 32, through hole 4, gasket 5.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0035] The specific content of the present invention is described in detail below in combination with the drawings and the embodiments.

[0036] Referring to FIGS. 1-5, the present invention provides a high-pressure bearable scale type bridge rubber bearing, comprising spring rubber vibration reduction pad assemblies 1, a flexible steel plate assembly 2 and a rubber bearing body 3. The rubber bearing body 3 comprises an outer rubber portion 31 and an inner rubber portion 32; the outer rubber portion 31 is wrapped around the outside of the spring rubber vibration reduction pad assemblies 1 and the flexible steel plate assembly 2; the spring rubber vibration reduction pad assemblies 1 are arranged on the upper side and the lower side of the inner rubber portion 32; the flexible steel plate assembly 2 is fixedly mounted between the spring rubber vibration reduction pad assemblies 1; and the spring rubber vibration reduction pad assemblies 1 and the flexible steel plate assembly 2 are wrapped around the inner rubber portion 32.

[0037] Further, the flexible steel plate assembly 2 comprises a plurality of arch-shaped flexible steel plates 21; the arch-shaped flexible steel plates 21 are mutually combined and spliced in a successive lap joint manner to form a cylindrical structure with a waist sunken; and the inner rubber portion 32 is arranged in the cylindrical structure. The arch-shaped flexible steel plates 21 are successively in lap joint to surround the inner rubber portion 32 and upper and lower groups of circular spring rubber vibration reduction pad assemblies 1 to form a closed a circle.

[0038] Further, in order to obtain stronger splicing tightness and supporting strength, a zigzag type splicing opening 22 is formed between adjacent arch-shaped flexible steel plates 21; and in a cross section, an upper steel plate of each arch-shaped flexible steel plate 21 is successively in lap joint to a lower steel plate of the front arch-shaped flexible steel plate 21, wherein the combined arch-shaped flexible steel plate 21 can produce an inward horizontal thrust when bearing a vertical reaction caused by a self weight of the structure and a secondary load, and transversely extrudes the interior rubber to make the bearing capacity of the rubber better; and when the combined arch-shaped flexible steel plate 21 bears an overlarge load produced by the bridge, each arch-shaped flexible steel plate assembly 2 can produce a deformation and is rapidly restored.

[0039] Further, the outer side surface of the outer rubber portion 31 is a sunken arch-shaped curved surface. In the arch-shaped outer rubber portion 31, an original linear segment is transformed into a curve from the top surface to the bottom surface, and the arch-shaped rubber is thoroughly wrapped around the interior arch-shaped flexible steel plates 21.

[0040] Further, each spring rubber vibration reduction pad assembly 1 comprises an upper steel plate layer 11, a lower steel plate layer 12, Fixing bolls 13, springs 14 and fixed columns 15; a plurality of fixed columns 15 are fixedly arranged on the upper surface of the lower steel plate layer 12 at uniform intervals; threaded holes 151 are formed in the fixed columns 15; through holes 4 are formed in the upper steel plate layer 11; the upper steel plate layer 11 is fixed to the fixed columns 15 by the fixing bolts 13 penetrating through the through holes 4; and the springs 14 are sleeved at the peripheries of the fixed columns 15. The through holes 4 formed in the steel plate are circular holes and have diameters slightly larger than those of the fixing bolts 13. Through the springs 14 arranged at the externals of the fixed columns 15, the springs 14 are distributed at an equal interval; by using small elasticity modulus of the springs 14, the springs 14 have the characteristics of having large elastic deformations after being loaded and effectively absorbing shocks and vibration, and then the overall elasticity of the structure is improved; and meanwhile, by using the principle that the rigidity is improved after parallel connection of the springs 14, the overall rigidity of the spring rubber vibration reduction pad assemblies 1 is improved, and the overall bearing capacity is increased.

[0041] Further, the fixed columns 15 are specifically arranged in a circular array; and heights of the springs 14 sleeved outside the fixed columns 15 are identically set.

[0042] Further, a gasket 5 is arranged between each fixing bolt 13 and the upper surface of the upper steel plate layer 11. Depths of the threaded holes 151 are adjustably set; the fixing bolts 13 are arranged as outer hexagon bolts; the gaskets 5 are further sleeved on the fixing bolts 13; and the bottoms of the gaskets 5 are attached to the tops of upper round steel plates.

[0043] Further, each fixed column 15 is of an eccentric elliptic platform shaped structure; and an ellipse on the bottom surface, an ellipse on the top surface and the side surface of an eccentric elliptic platform form a symmetric key shaped body. An eccentric elliptic platform shaped structure of each fixed column 15 facilitates bearing of a horizontal force produced in a direction of a bridge axis.

[0044] Further, a length of a long axis of the ellipse on the bottom surface of the fixed column 15 is consistent to the radius of each spring 14.

[0045] Further, in order to obtain stronger load bearing strength and buffering effect, each fixed column 15 is made of rubber with viscoelasticity, weak hardness and high damping.

[0046] This embodiment of the present invention can effectively conduct vibration reduction and earthquake resistance during use of the rubber bearing. By using small elasticity modulus of each spring 14, the rubber bearing has a relatively large elastic deformation after being loaded and can effectively absorb shock and vibration. The arch-shaped flexible combined steel plate is set to be capable of applying a reverse horizontal thrust to the interior when being under a load produced by an upper portion; and meanwhile, the combined steel plate can further exert the sealing effect to the interior rubber and may delay season cracking of the rubber.

[0047] At last, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and shall not be construed as limitation. Although the present invention is described in detail with reference to preferred embodiments, ordinary skill in the art should understand that modifications or equivalent substitutions may be made on the technical solutions of the utility model without departing from the spirit and the scope of the technical solutions of the present invention, all of which should be contained within the scope of the claims of the present invention.

[0048] The used standard parts in the present invention may all be commercially available, and special-shaped parts may be customized according to descriptions in the specification and the drawings. The specific connecting modes of various parts may employ mature conventional means such as bolts, rivets and welding in the prior art; the used machinery, parts and devices are all of conventional models in the prior art; and circuit connection employs a conventional connection mode in the prior art, which will not be described in detail any more here.

[0049] In description of the present invention, unless otherwise expressly specified and defined, the terms “mounted”, “connected”, “coupled” and “fixed” should be understood broadly, for example, as fixed connection, detachable connection or integration; mechanical connection or electrical connection; direct connection, connection through an intermediary medium, communicating between interiors of two elements or interacting between two elements. The meanings of above terms in the present invention may be understood in specific cases to those skilled in the art.