CN209779924U - high-damping rubber support - Google Patents

Abstract

The utility model provides a high damping rubber support, this support includes: rubber layer, last shrouding, lower shrouding, upper seat board and lower bedplate. The upper sealing plate is provided with a first through hole and is arranged on the rubber layer and used for fixing the upper side of the rubber layer. The lower sealing plate is provided with a second through hole and arranged below the rubber layer and used for fixing the lower side of the rubber layer. The upper seat plate is arranged on the upper surface of the upper sealing plate and used for fixing the upper side of the upper sealing plate. The lower seat plate is arranged below the lower sealing plate and used for fixing the lower side of the lower sealing plate, and the upper seat plate is connected with the lower seat plate in a clamping mode. The utility model provides a rubber support can also provide certain drawing force when accomplishing good anti-seismic performance, prevents that the support from receiving the pulling force and being destroyed, and this support can also inject the deformation of support in addition, prevents that deformation is excessive and damage rubber support.

Description

High-damping rubber support

Technical Field

The utility model relates to a building support technical field especially relates to rubber support, specifically is a high damping rubber support.

Background

the support has very big effect in modern architectural design, brings harm for the building in order to prevent vibrations, and the designer can set up damping device in the building usually, and damping device can reduce the vibration amplitude of building by a wide margin and change the vibration frequency of building, prevents that vibrations from bringing the damage for the building.

Among the prior art there are many types of support, wherein not lack the rubber support, the rubber support has outstanding performance in the aspect of taking precautions against earthquakes, and rubber can be corrosion-resistant moreover, can avoid damaging because of corroding in long-term use, and the cost of manufacture of rubber is low moreover, and the technology degree of difficulty is also lower relatively, is fit for mass production. Rubber itself has fine elasticity, but its damping characteristic of self is less than weak, generally will use with the attenuator cooperation, and the cost will be than higher like this, and current high damping rubber support does not have stop device on the horizontal direction, can cause steel sheet and lower steel sheet to take place great relative displacement on the support when support horizontal direction atress is great, causes the support to damage. In addition, the support generally receives pressure, and when the support received the pulling force under special circumstances, current support all hardly kept original state, can damage under the effect of pulling force.

Therefore, a rubber support with a structure for resisting a drawing force and a good damping effect, which can control a displacement deformation amount of the support while achieving a good anti-vibration effect, is urgently needed by those skilled in the art.

Disclosure of Invention

An object of the utility model is to overcome prior art not enough, provide a high damping rubber support. This support can realize fine shock attenuation effect, but also can control the deformation volume of support to a certain extent, prevents that the horizontal deformation of support from damaging, in addition, the support can also provide and prevent that vertical pulling force is too big and lead to the support to damage, because its buckle structure, so the support can bear very big drawing force on vertical.

The utility model provides a pair of high damping rubber support, this support includes: a rubber layer; the upper sealing plate is provided with a first through hole and is arranged on the rubber layer and used for fixing the upper side of the rubber layer; the lower sealing plate is provided with a second through hole and is arranged below the rubber layer and used for fixing the lower side of the rubber layer; the upper seat plate is arranged on the upper surface of the upper sealing plate and used for fixing the upper side of the upper sealing plate; and the lower seat plate is arranged below the lower sealing plate and used for fixing the lower side of the lower sealing plate, and the upper seat plate is clamped with the lower seat plate.

the utility model discloses an among the concrete embodiment, this support still includes: and the stiffening steel plate is arranged in the rubber layer and is used for enhancing the pressure resistance of the rubber layer.

the utility model discloses an among the specific embodiment, the rubber layer go up the shrouding down the shrouding with the stiffening steel sheet is together fixed through vulcanization technology.

in a specific embodiment of the present invention, the upper seat plate includes an upper plate and a first cylinder structure, wherein the upper plate is square, circular or rectangular; and the first cylindrical structure is arranged below the upper plate, and the lower end of the first cylindrical structure is provided with a plurality of first convex bodies perpendicular to the axis.

In a specific embodiment of the present invention, the lower base plate includes a lower plate and a second cylinder structure, wherein the lower plate is square, circular or rectangular; and the second cylindrical structure is arranged above the lower plate, and the upper end of the second cylindrical structure is provided with a plurality of second convex bodies perpendicular to the axis.

The first convex bodies are arranged on the upper base plate, the second convex bodies are arranged on the lower base plate, the first convex bodies are arranged on the lower base plate, the second convex bodies are arranged on the upper base plate, the second convex bodies are arranged on the lower base plate, and the first convex bodies are arranged on the upper base plate and the lower base plate.

As an embodiment of the present invention, the support further has a buckle structure, the buckle structure includes: the lower fixing part is fixed on the lower seat plate through screws; and a third cylindrical structure disposed on the lower fixing portion and surrounding the rubber layer, the third cylindrical structure having a plurality of third protrusions perpendicular to the axis at an upper end thereof.

The utility model discloses an among the concrete implementation, adjacent two have the space between the first convex body, adjacent two also have the space between the third convex body, the third convex body can be through adjacent two space between the first convex body, just first convex body can be through adjacent two space between the third convex body, first convex body with after the third convex body is rotatory to be overlapped, go up the bedplate with the mutual chucking of buckle structure.

The utility model discloses an among the specific embodiment, the rubber layer comprises the stack of multilayer rubber gasket, the outward flange interconnect of rubber gasket is as an organic whole.

The outer edge of the uppermost rubber gasket of the rubber layer extends upwards perpendicular to the upper surface of the rubber layer and surrounds the upper sealing plate; the outer edge of the lowermost rubber gasket of the rubber layer extends downwards perpendicular to the lower surface of the rubber layer and surrounds the lower sealing plate.

According to the above-mentioned embodiment of the utility model, the utility model provides a pair of high damping rubber support has following benefit: the special rubber structure of the rubber support can ensure that the support has a certain degree of elastic variable, can also achieve a high damping effect, and avoids the phenomenon that the building body excessively vibrates. On the other hand, this special connection structure of rubber support can provide a spacing effect when the support atress takes place to incline to warp, prevents that rubber support from causing the damage of rubber support because of deformation is excessive, and can also prevent on vertical that the drawing force from causing the damage to the support. Compared with the existing design, the rubber support has better advantages in safety and durability.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

drawings

The accompanying drawings, which are incorporated in and constitute a part of the specification of the invention, illustrate exemplary embodiments of the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a cross-sectional view of a first embodiment of a high-damping rubber support according to the present invention.

Fig. 2 is a cross-sectional view of a second embodiment of the high damping rubber mount according to the present invention.

Fig. 3 is a cross-sectional view of a third embodiment of a high-damping rubber support according to the present invention.

Fig. 4 is a bottom view of the upper seat plate of the high damping rubber support according to the present invention.

fig. 5 is a top view of the lower seat plate of the high damping rubber bearing according to the present invention.

Fig. 6 is a top view of the fastening structure of the high damping rubber support according to the present invention.

3 fig. 3 7 3 is 3 a 3 top 3 view 3 of 3 a 3 cross 3 section 3 a 3- 3 a 3 of 3 a 3 high 3 damping 3 rubber 3 mount 3 according 3 to 3 the 3 present 3 invention 3. 3

3 fig. 3 8 3 is 3 a 3 bottom 3 view 3 of 3 a 3 cross 3 section 3 a 3- 3 a 3 of 3 a 3 high 3 damping 3 rubber 3 mount 3 according 3 to 3 the 3 present 3 invention 3. 3

Description of reference numerals:

1-a rubber layer, 2-an upper sealing plate, 3-a lower sealing plate, 4-an upper seat plate, 5-a lower seat plate, 6-a buckle structure, 7-a stiffening steel plate and 8-a screw;

21-a first through hole, 31-a second through hole, 41-an upper plate, 42-a first cylinder structure, 51-a lower plate, 52-a second cylinder structure, 61-a lower fixing part and 62-a third cylinder structure;

421-first convexity, 521-second convexity, 621-third convexity.

Detailed Description

Reference will now be made in detail to various exemplary embodiments of the invention, which should not be considered limiting of the invention, but rather should be understood to be a more detailed description of certain aspects, features and embodiments of the invention.

it will be apparent to those skilled in the art that various modifications and variations can be made in the embodiments of the present disclosure without departing from the scope or spirit of the disclosure. Other embodiments will be apparent to those skilled in the art from consideration of the specification. The specification and examples are exemplary only.

Fig. 1 is a cross-sectional view of a first embodiment of a high damping rubber support according to the present invention. The rubber layer is located between last shrouding and the lower shrouding in the picture, and goes up the shrouding and the outer edge of shrouding down is wrapped up by the extension limit on rubber layer, goes up the bedplate and passes through the fix with screw with last shrouding, and the bedplate passes through the fix with screw with lower shrouding down, goes up the bedplate and connects down between the bedplate for the support also has certain stretch-proofing effect on vertical.

In the embodiment shown in fig. 1, the support comprises: rubber slab 1, go up shrouding 2, lower halving 3, upper seat board 4 and lower seat board 5. Wherein, the upper sealing plate 2 is provided with a first through hole 21, and the upper sealing plate 2 is arranged on the rubber layer 1 and is used for fixing the upper side of the rubber layer 1. The lower sealing plate 3 has a second through hole 31, and the lower sealing plate 3 is disposed below the rubber layer 1 for fixing the lower side of the rubber layer 1. First through-hole 21 and second through-hole 31 are for being used for the installation locating pin when the preparation support, play the effect of location, guarantee that the installation of support is big deviation not appeared, make the support can reach best installation effect, can guarantee during the use that the atress of support is even, are favorable to prolonging the life of support like this. The upper seat plate 4 is arranged on the upper surface of the upper sealing plate 2, and the upper seat plate 4 is used for fixing the upper side of the upper sealing plate 2. The lower seat plate 5 is arranged below the lower sealing plate 3 and used for fixing the lower side of the lower sealing plate 3, and the upper seat plate 4 is connected with the lower seat plate 5 in a clamping mode.

In the embodiment of the embodiment shown in fig. 1, the support further comprises a stiffening steel plate 7, and the stiffening steel plate 7 is arranged inside the rubber layer 1 and is used for enhancing the pressure resistance of the rubber layer 1. In order to improve the pressure resistance and damping of the rubber layers 1, stiffening steel plates 7 are required to be additionally arranged between the rubber layers 1, and the stiffening steel plates 7 can reduce the deformation of the rubber layers 1 and prevent the excessive deformation of the support. The rubber layer 1, the upper sealing plate 2, the lower sealing plate 3 and the stiffening steel plate 8 are fixed together through a vulcanization process. The fixing together through the vulcanization treatment is to strengthen the unity, can also prevent dust or rainwater entering the inside of support, increases the life of support.

The upper deck 4 comprises an upper deck 41 and a first cylindrical structure 42, wherein the upper deck 41 is square, circular or rectangular in shape. The first cylindrical structure 42 is disposed under the upper plate 41, and the lower end of the first cylindrical structure 42 has a plurality of first protrusions 421 perpendicular to the axis. As shown in fig. 4, which is a bottom view of the upper seat plate 5, in the embodiment of the upper seat plate 4 shown in fig. 4, the upper seat plate 4 has 4 first protrusions 421, the first protrusions 421 uniformly surround the first cylindrical structure 42, and the first protrusions 421 all extend into the cylinder of the first cylindrical structure 42, that is, the first protrusions 421 extend toward the axial center of the first cylindrical structure 42. The lower plate 5 comprises a lower plate 51 and a second cylindrical structure 52, wherein the lower plate 51 is square, circular or rectangular in shape. The second cylindrical structure 52 is disposed on the lower plate 51, and the upper end of the second cylindrical structure 52 has a plurality of second protrusions 521 perpendicular to the axis. As shown in fig. 5, which is a top view of the lower seat plate 5, in the embodiment of the lower seat plate 5 shown in fig. 5, the lower seat plate 5 has 4 second protrusions 521, the second protrusions 521 uniformly surround the second cylindrical structure 52, and the second protrusions 521 all extend out of the second cylindrical structure 52.

A space is formed between two adjacent first protrusions 421, and the space is uniformly distributed in the cylinder of the first cylinder structure 42, and the spaces are the same in size. A space is also provided between two adjacent second protrusions 521, and the space is uniformly distributed outside the second cylinder structure 52, and the spaces are the same in size. Each second convex body 521 can pass through the space between any two adjacent first convex bodies 421, and each first convex body 421 can pass through the space between any two adjacent second convex bodies 521, as shown in fig. 7, the first convex body 421 and the second convex body 521 can reach an overlapping state after rotating, at this time, the upper seat plate 4 and the lower seat plate 5 are clamped with each other, and the longitudinal direction cannot be separated. The size of the first convex body 421 is slightly smaller than or equal to the spacing space between two adjacent second convex bodies 521, and the size of the second convex body 521 is also slightly smaller than or equal to the spacing space between two adjacent first convex bodies 421. When being installed, the first protrusions 421 pass through the space between two adjacent second protrusions 521, and the second protrusions 521 also pass through the space between two adjacent first protrusions 421. Then, the upper seat plate 4 and the lower seat plate 5 are relatively rotated until the first convex body 421 and the second convex body 521 are overlapped, and at the moment, the upper seat plate 4 and the lower seat plate 5 are clamped, so that a large drawing force can be borne in the longitudinal direction.

3 fig. 3 8 3 is 3 a 3 bottom 3 view 3 of 3 a 3 cross 3 section 3 a 3- 3 a 3 of 3 the 3 high 3 damping 3 rubber 3 bearing 3 provided 3 by 3 the 3 present 3 invention 3, 3 in 3 this 3 view 3, 3 the 3 central 3 axis 3 of 3 the 3 second 3 cylinder 3 structure 3 52 3 of 3 the 3 lower 3 bearing 3 5 3 coincides 3 with 3 the 3 central 3 axis 3 of 3 the 3 upper 3 seat 3 plate 3 4 3, 3 so 3 that 3 the 3 bearing 3 is 3 stressed 3 uniformly 3. 3

In this embodiment, the rubber layer 1 is formed by stacking a plurality of rubber gaskets, and the outer edges of the rubber gaskets are connected with each other to form a whole, wherein the outer edge of the uppermost rubber gasket of the rubber layer 1 extends upward perpendicular to the upper surface of the rubber layer 1 and surrounds the upper sealing plate 2. The outer edge of the lowermost rubber gasket of the rubber layer 1 extends downward perpendicular to the lower surface of the rubber layer 1, and surrounds the lower sealing plate 3. In addition, the rubber layer 1, the upper sealing plate 2, the lower sealing plate 3 and the stiffening steel plate 7 are fixed together through a vulcanization process. The fixing together through the vulcanization treatment is in order to strengthen the wholeness of support, can also prevent that dust or rainwater from getting into the inside of support, increases the life of support. The upper seat plate 4 on the upper sealing plate 2 is fixed with the upper sealing plate 2 through a screw 8. The lower seat plate 5 below the lower closure plate 3 is also secured to the lower closure plate 3 by screws 8. The screw 8 is connected with the support, so that the support is convenient to disassemble and maintain. And the use of the screw 8 for connection can also prevent the upper seat plate 4 and the lower seat plate 5 from rotating relatively during the use process, so that the structure of the support is separated and even the support is damaged.

fig. 2 is a cross-sectional view of a second embodiment of a high damping rubber mount according to the present invention. The difference between this embodiment and the first embodiment is that the seat in this embodiment comprises an upper seat plate 4, a lower seat plate 5 and a snap structure 6. Wherein, the upper seat plate 4 comprises an upper plate 41 and a first cylindrical structure 42, wherein the upper plate 41 is square, circular or rectangular in shape. The first cylindrical structure 42 is disposed under the upper plate 41, and the lower end of the first cylindrical structure 42 has a plurality of first protrusions 421 perpendicular to the axis. The first protrusions 421 surround the first cylindrical structure 42 uniformly, and the first protrusions 421 extend into the cylinder of the first cylindrical structure 42, that is, the first protrusions 421 extend toward the axis of the first cylindrical structure 42, in this embodiment, there are 4 first protrusions 421. The lower seat plate 5 is a round or square steel plate. The buckle structure 6 includes: a lower fixing portion 61 and a third cylindrical structure 62. The lower fixing portion 61 is fixed to the lower seat plate 5 by screws 8. The third cylindrical structure 62 is disposed above the lower fixing portion 61 around the outside of the rubber layer 1, and the upper end of the third cylindrical structure 62 has a plurality of third protrusions 621 perpendicular to the axis. As shown in fig. 6, which is a top view of the snap structure 6, in the embodiment of the snap structure 6 shown in fig. 6, the snap structure 6 has 4 third protrusions 621, the third protrusions 621 uniformly surround the third cylindrical structure 62, and the third protrusions 621 all extend out of the third cylindrical structure 62.

A space is formed between two adjacent first protrusions 421, and the space is uniformly distributed in the cylinder of the first cylinder structure 42, and the spaces are the same in size. An interval space is also formed between two adjacent third protrusions 621, and the interval space is uniformly distributed outside the third cylindrical structure 62, and the sizes of the interval spaces are the same. Every third convex body 621 can both pass through the interval space between two arbitrary adjacent first convex bodies 421, and every first convex body 421 can both pass through the interval space between two arbitrary adjacent third convex bodies 621, can reach the overlapped state after first convex body 421 and the rotation of third convex body 621, and upper seat board 4 and buckle structure 6 chucking each other this moment, and longitudinal direction can not separate. The size of the first protrusions 421 is slightly smaller than or equal to the space between two adjacent third protrusions 621, and the size of the third protrusions 621 is also slightly smaller than or equal to the space between two adjacent first protrusions 421. When mounted, the first protrusions 421 pass through the space between two adjacent third protrusions 621, and the third protrusions 621 pass through the space between two adjacent first protrusions 421. Then, the upper seat plate 4 and the buckle structure 6 are relatively rotated until the first convex body 421 and the third convex body 621 coincide with each other, and at the moment, the upper seat plate 4 and the buckle structure 6 are clamped, so that a large drawing force can be borne in the longitudinal direction.

fig. 3 is a cross-sectional view of a third embodiment of a high damping rubber mount according to the present invention. The difference between the embodiment shown in fig. 3 and the second embodiment is that the upper seat plate 4 has 4 first protrusions 421, the first protrusions 421 uniformly surround the first cylindrical structure 42, and the first protrusions 421 extend out of the first cylindrical structure 42. The fastening structure 6 has 4 third protrusions 621, the third protrusions 621 uniformly surround the third cylindrical structure 62, and the third protrusions 621 all extend into the cylinder of the third cylindrical structure 62, that is, the third protrusions 621 extend toward the axial center of the third cylindrical structure 62.

a space is formed between two adjacent first protrusions 421, and the space is uniformly distributed in the cylinder of the first cylinder structure 42, and the spaces are the same in size. An interval space is also formed between two adjacent third protrusions 621, and the interval space is uniformly distributed outside the third cylindrical structure 62, and the sizes of the interval spaces are the same. Every third convex body 621 can both pass through the interval space between two arbitrary adjacent first convex bodies 421, and every first convex body 421 can both pass through the interval space between two arbitrary adjacent third convex bodies 621, can reach the overlapped state after first convex body 421 and the rotation of third convex body 621, and upper seat board 4 and buckle structure 6 chucking each other this moment, and longitudinal direction can not separate. The size of the first protrusions 421 is slightly smaller than or equal to the space between two adjacent third protrusions 621, and the size of the third protrusions 621 is also slightly smaller than or equal to the space between two adjacent first protrusions 421. When mounted, the first protrusions 421 pass through the space between two adjacent third protrusions 621, and the third protrusions 621 pass through the space between two adjacent first protrusions 421. Then, the upper seat plate 4 and the buckle structure 6 are relatively rotated until the first convex body 421 and the third convex body 621 coincide with each other, and at the moment, the upper seat plate 4 and the buckle structure 6 are clamped, so that a large drawing force can be borne in the longitudinal direction.

in another embodiment, the support does not have the snap structure 6, and the upper plate 4 comprises an upper plate 41 and a first cylindrical structure 42, wherein the upper plate 41 is square, circular or rectangular in shape. The first cylindrical structure 42 is disposed under the upper plate 41, and the lower end of the first cylindrical structure 42 has a plurality of first protrusions 421 perpendicular to the axis. In this embodiment, the upper seat plate 4 has 4 first protrusions 421, the first protrusions 421 uniformly surround the first cylindrical structure 42, and the first protrusions 421 all extend out of the first cylindrical structure 42. The lower plate 5 comprises a lower plate 51 and a second cylindrical structure 52, wherein the lower plate 51 is square, circular or rectangular in shape. The second cylindrical structure 52 is disposed on the lower plate 51, and the upper end of the second cylindrical structure 52 has a plurality of second protrusions 521 perpendicular to the axis. In this embodiment, the lower seat plate 5 has 4 second protrusions 521, the second protrusions 521 uniformly surround the second cylindrical structure 52, and the second protrusions 521 all extend into the cylinder of the second cylindrical structure 52, that is, the second protrusions 521 extend toward the axial center of the second cylindrical structure 52.

A space is formed between two adjacent first protrusions 421, and the space is uniformly distributed in the cylinder of the first cylinder structure 42, and the spaces are the same in size. A space is also provided between two adjacent second protrusions 521, and the space is uniformly distributed outside the second cylinder structure 52, and the spaces are the same in size. Each second convex body 521 can pass through the space between any two adjacent first convex bodies 421, and each first convex body 421 can pass through the space between any two adjacent second convex bodies 521, the first convex bodies 421 and the second convex bodies 521 can reach an overlapped state after rotating, at this time, the upper seat plate 4 and the lower seat plate 5 are mutually clamped, and the longitudinal direction cannot be separated. The size of the first convex body 421 is slightly smaller than or equal to the spacing space between two adjacent second convex bodies 521, and the size of the second convex body 521 is also slightly smaller than or equal to the spacing space between two adjacent first convex bodies 421. When being installed, the first protrusions 421 pass through the space between two adjacent second protrusions 521, and the second protrusions 521 also pass through the space between two adjacent first protrusions 421. Then, the upper seat plate 4 and the lower seat plate 5 are relatively rotated until the first convex body 421 and the second convex body 521 are overlapped, and at the moment, the upper seat plate 4 and the lower seat plate 5 are clamped, so that a large drawing force can be borne in the longitudinal direction.

The foregoing is only an illustrative embodiment of the present invention, and any equivalent changes and modifications made by those skilled in the art without departing from the spirit and principles of the present invention should fall within the protection scope of the present invention.

Claims (10)

1. A high damping rubber mount, comprising:

A rubber layer (1);

The upper sealing plate (2) is provided with a first through hole (21) and is arranged above the rubber layer (1) and used for fixing the upper side of the rubber layer (1);

The lower sealing plate (3) is provided with a second through hole (31) and is arranged below the rubber layer (1) and used for fixing the lower side of the rubber layer (1);

The upper seat plate (4) is arranged on the upper surface of the upper sealing plate (2) and is used for fixing the upper side of the upper sealing plate (2); and

The lower seat plate (5) is arranged below the lower sealing plate (3) and used for fixing the lower side of the lower sealing plate (3), and the upper seat plate (4) is clamped with the lower seat plate (5).

2. A high damping rubber mount according to claim 1 further comprising:

And the stiffening steel plate (7) is arranged inside the rubber layer (1) and is used for enhancing the pressure resistance of the rubber layer (1).

3. A high damping rubber mount according to claim 2 wherein said rubber layer (1), said upper sealing plate (2), said lower sealing plate (3) and said stiffening steel plate (7) are fixed together by a vulcanization process.

4. High damping rubber mount according to claim 1, characterized in that the upper seat plate (4) comprises an upper plate (41) and a first cylindrical structure (42), wherein,

The upper plate (41) is square, round or rectangular; and

The first cylindrical structure (42) is arranged below the upper plate (41), and the lower end of the first cylindrical structure (42) is provided with a plurality of first convex bodies (421) perpendicular to the axis.

5. the high damping rubber mount according to claim 4, wherein the lower seat plate (5) comprises a lower plate (51) and a second cylindrical structure (52), wherein,

The lower plate (51) is square, round or rectangular; and

The second cylindrical structure (52) is arranged above the lower plate (51), and the upper end of the second cylindrical structure (52) is provided with a plurality of second convex bodies (521) perpendicular to the axis.

6. The high damping rubber mount as claimed in claim 5, wherein a space is provided between two adjacent first protrusions (421), a space is provided between two adjacent second protrusions (521), the second protrusions (521) can pass through the space between two adjacent first protrusions (421), and the first protrusions (421) can pass through the space between two adjacent second protrusions (521), and after the first protrusions (421) and the second protrusions (521) are rotationally overlapped, the upper seat plate (4) and the lower seat plate (5) are clamped with each other.

7. the high damping rubber mount according to claim 4, characterized in that the mount further has a snap structure (6), said snap structure (6) comprising:

A lower fixing portion (61) fixed to the lower seat plate (5) by a screw (8); and

And a third cylindrical structure (62) arranged on the lower fixing part (61) and surrounding the outside of the rubber layer (1), wherein the upper end of the third cylindrical structure (62) is provided with a plurality of third convex bodies (621) vertical to the axis.

8. The high damping rubber mount according to claim 7, wherein a spacing space is provided between two adjacent first protrusions (421), a spacing space is provided between two adjacent third protrusions (621), the third protrusions (621) can pass through the spacing space between two adjacent first protrusions (421), and the first protrusions (421) can pass through the spacing space between two adjacent third protrusions (621), and after the first protrusions (421) and the third protrusions (621) are rotationally overlapped, the upper seat plate (4) and the snap structure (6) are clamped with each other.

9. The high damping rubber mount according to claim 1, wherein the rubber layer (1) is formed by stacking a plurality of rubber gaskets, and the outer edges of the rubber gaskets are integrally connected to each other.

10. The high damping rubber mount according to claim 9, wherein the outer edge of the uppermost rubber gasket of the rubber layer (1) extends upward perpendicular to the upper surface of the rubber layer (1) around the upper closure plate (2); the outer edge of the lowermost rubber gasket of the rubber layer (1) extends downwards perpendicular to the lower surface of the rubber layer (1) and surrounds the lower sealing plate (3).