3D VARIABLE DAMPING VIBRATION ISOLATOR BASED ON RUBBER FRICTION AND EXTRUSION MECHANISM

Abstract

A 3D variable damping vibration isolator based on rubber friction and extrusion mechanism is composed of a base, an upper plate, a vibration isolation spring, shaped bolts, lock nuts, damped rubber blocks and a shell. The damped rubber blocks are vulcanized and bonded to the external vertical surfaces of vertical steel angles uniformly distributed on the base and are opposite to each other in pairs; the upper end of each shaped bolt is fixed to the upper plate by upper and lower (two) lock nuts, and cross bars at the lower end are squeezed by the damped rubber blocks on both sides; contact surfaces of the damped rubber blocks and the shaped bolts are flat-a design of variable cross-section. The vibration isolation spring is sheathed between the base and a lug boss in the center of the upper plate.

Claims

1. A 3D variable damping vibration isolator based on rubber friction and extrusion mechanism, comprising a base, an upper plate, a vibration isolation spring, shaped bolts, lock nuts, damped rubber blocks and a shell; the center of the base is provided with a lug boss used for restricting the vertical vibration isolation spring, and four vertical steel angles are uniformly distributed around the lug boss; the damped rubber blocks- are vulcanized and bonded to the external vertical surfaces of vertical steel angles uniformly distributed on the base and are opposite to each other in pairs; the upper end of each shaped bolt is fixed to the upper plate by upper and lower lock nuts, and cross bars at the lower end are squeezed by the damped rubber blocks on both sides; the contact surfaces of the damped rubber blocks and the shaped bolts are flat-a design of variable cross-section; the vibration isolation spring- is sheathed between the base and a lug boss in the center of the upper plate; the shell is fixed to the base by screws, the upper end of each shaped bolt is threaded, the lower end is provided with at least two parallel cross bars, the friction surfaces of the end parts of the cross bars in contact with the damped rubber blocks are convex, and each friction surface is flat from the center to the periphery-a design of variable cross-section.

2. The 3D variable damping vibration isolator based on rubber friction and extrusion mechanism according to claim 1, wherein the damped rubber blocks are cuboid, and the friction surfaces of the damped rubber blocks in contact with the cross bars at the lower end of each shaped bolt are concave; the number of the friction surfaces is the same as the number of the cross bars at the lower end of each shaped bolt, the concave friction surfaces of the damped rubber blocks are seamlessly fitted with the convex friction surfaces of the shaped bolts, and each friction surface is flat from the center to the peripherya design of variable cross-section.

3. The 3D variable damping vibration isolator based on rubber friction and extrusion mechanism according to claim 1- or 2, wherein the upper end of each shaped bolt- is fixed to the upper plate by two lock nuts, and the position of the shaped bolt- is adjusted by changing the positions of the two lock nuts to ensure that the cross bars at the lower end of the shaped bolt- are always in the centers of the friction surfaces of the damped rubber blocks.

4. (canceled)

5. (canceled)

6. The 3D variable damping vibration isolator based on rubber friction and extrusion mechanism according to claim 1, wherein the center of the top surface of the upper plate is provided with a lug boss, the lug boss can bear the base of equipment requiring vibration isolation, and the center of the lug boss has a screw hole.

7. The 3D variable damping vibration isolator based on rubber friction and extrusion mechanism according to claim 2, wherein the center of the top surface of the upper plate is provided with a lug boss, the lug boss can bear the base of equipment requiring vibration isolation, and the center of the lug boss has a screw hole.

8. The 3D variable damping vibration isolator based on rubber friction and extrusion mechanism according to claim 3, wherein the center of the top surface of the upper plate is provided with a lug boss, the lug boss can bear the base of equipment requiring vibration isolation, and the center of the lug boss has a screw hole.

Description

DESCRIPTION OF DRAWINGS

[0014] FIG. 1 is a structural schematic diagram of a device of the present invention in a normal working condition.

[0015] FIG. 2 is an appearance schematic diagram of a device of the present invention in a normal working condition.

[0016] FIG. 3 is an isometric schematic diagram of a damped rubber block in a device of the present invention.

[0017] FIG. 4 is a sectional view of a damped rubber block in a device of the present invention.

[0018] FIG. 5 is an isometric schematic diagram of a shaped bolt in a device of the present invention.

[0019] FIG. 6 is a sectional view of a shaped bolt in a device of the present invention.

[0020] In the figures: 1 base; 2 upper plate; 3 vibration isolation spring; 4 shaped bolt; 5 lock nut; 6 damped rubber block; 7 shell.

DETAILED DESCRIPTION

[0021] The present invention will be further described below in combination with the drawings in the embodiment of the present invention.

[0022] FIG. 1 and FIG. 2 show structural and appearance schematic diagrams of a 3D variable damping vibration isolator based on rubber friction and extrusion mechanism in an embodiment of the present invention in a normal working condition. The vibration isolator is composed of a base 1, an upper plate 2, a vibration isolation spring 3, shaped bolts 4, lock nuts 5, damped rubber blocks 6 and a shell 7.

[0023] In the specific implementation process, the vibration isolator uses base 1 as a foundation, the center of the base 1 is provided with a lug boss used for restricting the vertical vibration isolation spring 3, four vertical steel angles are uniformly distributed around the lug boss, and the external vertical surfaces of the vertical steel angles are opposite to each other in pairs, which provides a certain horizontal deformation space for the vibration isolation spring 3, can bear the load produced when the damped rubber blocks 6 are squeezed, and improves the stability of the device.

[0024] In the specific implementation process, the lower end of the vibration isolation spring 3 is sheathed with the lug boss in the center of the base 1, and the upper end is sheathed with the lug boss in the center of the bottom surface of the upper plate 2, which restricts the position of the vibration isolation spring 3, and can ensure the horizontal deformation ability of the vibration isolation spring 3.

[0025] In the specific implementation process, the center of the top surface of the upper plate 2 is provided with a lug boss, the lug boss can bear the base of equipment requiring vibration isolation, and the center of the lug boss has a screw hole which can be connected with the equipment or base 1 above; the center of the bottom surface of the upper plate 2 is also provided with a lug boss which is used for restricting the vibration isolation spring 3 and transmitting the horizontal load of the upper plate 2 at the same time, thus to enable the vibration isolation spring 3 to have a horizontal deformation; in addition, four holes are formed around the lug bosses of the upper plate 2, which can allow the upper ends of the shaped bolts 4 to pass through.

[0026] In the specific implementation process, the cuboid damped rubber blocks 6 shown in FIG. 3 and FIG. 4 are vulcanized and bonded to the external vertical surfaces of the vertical steel angles uniformly distributed on the base 1 and are opposite to each other in pairs, the two friction surfaces of the damped rubber blocks 6 in contact with each cross bar at the lower end of each shaped bolt 4 are concave and symmetric in any diameter direction, each friction surface is flat from the center to the periphery-a design of variable cross-section, and the outermost rim of each damped rubber block 6 is provided with a protective layer with a certain thickness and can resist part of an impact load.

[0027] In the specific implementation process, the upper end of each shaped bolt 4 shown in FIG. 5 and FIG. 6 is threaded, and the upper end of the bolt penetrates through a hole reserved in the upper plate 2 and is then fixed to the upper plate 2 by upper and lower (two) lock nuts 5; the lower end of each shaped bolt 4 is provided with two parallel cross bars, the two friction surfaces of the end parts of either cross bar in contact with the damped rubber blocks 6 are convex, and each friction surface is flat from the center to the periphery-a design of variable cross-section. The initial position of each cross bar at the lower end of each + shaped bolt 4 is in the center of each friction surface of a corresponding damped rubber block 6, and the + shaped bolt 4 and the damped rubber block 6 are squeezed by each other; after the vibration isolator is subjected to a certain load, the position of the shaped bolt 4 can be adjusted by the two lock nuts 5 to ensure that the cross bars at the lower end of each bolt are always in the centers of the friction surfaces of the corresponding damped rubber blocks 6.

[0028] In the specific implementation process, the shell 7 is fixed to the base 1 by screws.

[0029] In the specific implementation process, when the vibration isolator is in vertical vibration, the stiffness is provided by the vibration isolation spring 3, the shaped bolts 4 is driven by the upper plate 2 to move relative to the damped rubber blocks 6, certain friction damping can be generated between the shaped bolts 4 and the damped rubber blocks 6, and as the contact surfaces of the rubber blocks and the bolts are flat-a design of variable cross-section, the damping is small at an equilibrium position and large at a position away from the equilibrium position, which can not only ensure the vibration isolation effect, but also effectively suppress resonance.

[0030] In the specific implementation process, when the vibration isolator is in horizontal vibration, the vibration isolation spring 3 has a horizontal deformation under the action of a horizontal vibration force, the damped rubber blocks 6 not in vibration direction are extruded by the shaped bolts 4 to provide horizontal stiffness, the damped rubber blocks 6 in vibration direction will move in vibration direction relative to the shaped bolts 4 to provide certain damping, and as the contact surfaces of the rubber blocks and the bolts are flat-a design of variable cross-section, the isolation device will also have variable damping in horizontal vibration, which can both ensure the vibration isolation effect and effectively suppress resonance. In addition, because each shaped bolt 4 is located between two opposite damped rubber blocks 6, and both ends of each cross bar at the lower end are squeezed by the damped rubber blocks 6, the present invention has a good self-resetting ability in horizontal vibration.

[0031] To sum up, the 3D variable damping vibration isolator based on rubber friction and extrusion mechanism in the present invention has the characteristics that the damping is small at an equilibrium position and large at a position away from the equilibrium position in all directions of vibration, and therefore has three-way variable damping; the damping parameters of the vibration isolation device can be changed by changing the size of the contact surfaces of the damped rubber blocks 6 and the shaped bolts 4, and the horizontal stiffness can be designed by changing the hardness of the damped rubber blocks 6, therefore the present invention has designable three-way stiffness and damping. The present invention has a simple structure, a controllable cost and a good application prospect.