KR20080028014A - Shear deformational rubber for improvement of damping and vibration insulating performance - Google Patents

Abstract

Vibration-insulation rubber used for a double flooring system is provided to damp shock by performing large deformation while maintaining rigidity through shear strain. Vibration-insulation rubber is equipped with L-type structures(10,50) including a horizontal plate(11,51) and vertical plates(12,52), the other type structure(30) including two vertical plates(31,33) and an upper horizontal plate(32), and rubber(20,40). The L-type structures are faced to each other about the structure arranged in the center. Two rubber is fitted to each of the vertical plates of the L-type structures and simultaneously fitted to each of the vertical plates of the structures.

Description

Shear deformational rubber for improvement of damping and vibration insulating performance

1 is a perspective view of a vibration damping rubber according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view taken along line AA ′ of FIG. 1.

3 is a cross-sectional view taken along line BB ′ of FIG. 1.

4 is a plan view of a damping rubber according to a first embodiment of the present invention.

5 is a structural diagram of a first shock absorbing structure of the damping rubber according to the first embodiment of the present invention.

6 is a plan view of a damping rubber according to a second embodiment of the present invention.

7 is a structural diagram of a second shock absorbing structure of the damping rubber according to the second embodiment of the present invention.

8 is a cross-sectional view of the vibration damping rubber according to the third or fourth embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: first L-shaped structure

11: horizontal plate of the first L-shaped structure

12: vertical plate of the first L-shaped structure

20: first rubber

30: first fin structure

30a: second finned structure

31: first vertical plate of the fin structure

32: Horizontal plate of the curved structure

33: second vertical plate of the curved structure

34: third vertical plate of curved structure

35: fourth vertical plate of curved structure

40: second rubber

50: second L-shaped structure

51: horizontal plate of the second L-shaped structure

52: vertical plate of the second L-shaped structure

60: third L-shaped structure

61: horizontal plate of the third L-shaped structure

62: vertical plate of the third L-shaped structure

70: third rubber

80: fourth rubber

90: fourth L-shaped structure

91: horizontal plate of the fourth L-shaped structure

92: vertical plate of the fourth L-shaped structure

The present invention relates to vibration damping rubber mainly used in the double-floor system, and more particularly, it is possible to maintain the rigidity through the shear deformation, but large deformation can be advantageous for the initial impact force relaxation and high damping ratio, high vibration insulation It is about damping rubber with performance.

Existing dust-proof rubber for vibration insulation exists in various forms, but most of them have a mechanism for vibration insulation through compression and tensile deformation. However, rubber is a material in which the behavior of compressive or tensile behavior changes nonlinearly with temperature, load speed, or time history, and the proper physical properties for the excitation conditions due to the dynamic load loading through compression and tension at the lower part of the object The design of the rubber is difficult.

Japanese Patent Laid-Open No. 3772715 and Japanese Patent Laid-Open No. 2003-97634 disclose a vibration damping device, but its use is for an automobile body and its structure is very complicated.

Japanese Patent Application Laid-Open No. 2001-73303 discloses an elastic anti-vibration rubber, characterized in that a hollow hole is formed in a cross section of a rubber sheet so that the deformation of the rubber sheet causes compression deformation and shear deformation under the compression load on the rubber sheet. Is for railway track structure and the structure is also different from the present invention.

An object of the present invention is to provide a vibration damping rubber having a high vibration insulation performance to maintain the rigidity through shear deformation, but large deformation can be advantageous to alleviate the initial impact force and have a high damping ratio.

In order to achieve the above object, the present invention provides an L-type structure or an inverted L-type structure, a ┌┐-type structure or └ ┘-type structure, and vibration damping rubber having rubber.

The vibration damping rubber for vibration insulation according to the first embodiment of the present invention includes an L-type structure consisting of a horizontal plate and a vertical plate, a V-shaped structure consisting of two vertical plates and an upper horizontal plate, and rubber. The two L-shaped structures are arranged so as to face each other with the center of the curved structure disposed at the center, and the two rubbers are coupled to each vertical plate of the curved structure at the same time as the two rubbers are joined to the vertical plates of the respective L-shaped structures. It features.

The vibration damping rubber for vibration insulation according to the second embodiment of the present invention includes an L-type structure consisting of a horizontal plate and a vertical plate, a V-shaped structure consisting of four vertical plates and an upper horizontal plate, and rubber. Four L-shaped structures are arranged so that two pairs face each other with the center of the curved structure arranged at the center, and the four rubbers are bonded to the vertical plates of each L-shaped structure and to each vertical plate of the curved structure. It is characterized by.

The vibration damping rubber for vibration insulation according to the third embodiment of the present invention is provided with an inverted L-type structure consisting of a horizontal plate and a vertical plate, a └┘ structure consisting of two vertical plates and a lower horizontal plate, and rubber. In the center of the └ 구조물 structure, two inverted L-shaped structures are arranged to face each other, and the two rubbers are joined to the vertical plates of each inverted L-shaped structure, It is characterized by being combined.

The vibration damping rubber according to the fourth embodiment of the present invention is provided with an inverted L-type structure consisting of a horizontal plate and a vertical plate, a └┘ structure consisting of four vertical plates and a lower horizontal plate, and rubber. └┘-shaped structures arranged in the center, 4 inverted L-shaped structures are arranged so as to face each other two pairs, four rubbers are bonded to the vertical plate of each inverted L-shaped structure, and at the same time each number of └┘-shaped structures It is characterized in that coupled to the direct plate.

According to the first and second embodiments of the present invention, the horizontal plate of the L-shaped structure is in contact with the bottom surface, the rubber is inclined toward the X-shaped structure to form a structure in which the X-shaped structure is floating, accordingly It is characterized by having a deformation space as much as the inclined height.

According to the third and fourth embodiments of the present invention, the horizontal plate of the └┘-type structure is in contact with the bottom surface, the rubber is inclined toward the reverse L-type structure to form a structure in which the reverse L-type structure is floating, accordingly Characterized by having a deformation space as much as the inclined height of the.

In the present invention, the inclined portion of the rubber is preferably made of an arc shape concave toward the center of the rubber, shear deformation can be easily made due to the arc-shaped structure of the rubber.

In the present invention, the L-type structure and the ┌┐-type structure and the reverse L-type structure and └ ┘ type structure may be made of metal, plastic or wood.

The vibration damping rubber according to the present invention maintains rigidity through shear deformation, but is capable of large deformation (large deformation occurs), which is advantageous for easing initial impact force, and has a high damping ratio compared to conventional rubber, and has excellent vibration damping performance and static load. The load-bearing design is also easy and the mechanical deformation is excellent due to the large deformation.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a vibration damping rubber according to a first embodiment of the present invention, FIG. 2 is a cross-sectional view taken along line AA ′ of FIG. 1, and FIG. 3 is a cross-sectional view taken along line B-B ′ of FIG. 1.

The damping rubber according to the first embodiment of the present invention is composed of two L-shaped structures (10, 50), two rubber (20, 40) and a k-shaped structure (30).

The first L-shaped structure 10 and the second L-shaped structure 50 serve as a support in contact with the floor surface to be constructed, the horizontal plates 11 and 51 having a length a and the vertical plates 12 having a height b, respectively. , 52) and its cross section forms an L-shape.

The first fin-shaped structure 30 is composed of two vertical plates 31 and 33 and one horizontal plate 32. The first vertical plate 31 and the horizontal plate 32 and the second vertical plate ( 33) are connected and its cross section forms a c-shape.

The L-shaped structures 10 and 50 and the first n-type structure 30 are made of a metal plate such as an iron plate, and may be made of plastic or wood.

The rubbers 20 and 40 are disposed between the L-shaped structures 10 and 50 and the first fin-shaped structure 30. Specifically, the first fin-shaped structure 30 is disposed in the center, and the two L-shaped structures 10 and 50 are disposed to face each other with respect to the first fin-shaped structure 30, and the first rubber 20 is coupled to the vertical plate 12 of the first L-shaped structure 10 and simultaneously to the first vertical plate 31 of the first fin-shaped structure 30, and likewise to the second rubber 40. Is coupled to the vertical plate 52 of the second L-shaped structure 50 and simultaneously to the second vertical plate 33 of the first n-type structure 30. Bonding between the rubber (20, 40) and the L-shaped structure (10, 50) and the first n-type structure 30 is made using an adhesive or the like.

The rubber 20, 40 has a width c and its cross section is formed in a parallelogram, and is made of a dustproof rubber or the like.

The rubbers 20 and 40 are inclined toward the first fin-shaped structure 30 and are combined with the first fin-shaped structure 30 to form a structure in which the first fin-shaped structure 30 is floated. Accordingly, the damping rubber according to the present invention has a deformation space equal to the inclined height h of the rubbers 20 and 40.

The inclined portion of the rubber (20, 40) is made of an arc shape concave toward the center of the rubber (20, 40), due to the arc-shaped structure of the rubber (20, 40) can be easily sheared.

In this embodiment the main load bearing direction is in the y direction and shear deformation occurs in this direction. Deformation occurs in the y and z directions, and little deformation occurs in the x direction due to the support of the L-shaped structures 10 and 50 and the rubbers 20 and 40. Depending on the load conditions, the dimensions a, b, h, etc. can be adjusted.

4 is a plan view of the damping rubber according to the first embodiment of the present invention, when viewed from above the first L-shaped structure 10, the first rubber 20, the first ┌┐ type structure 30, the second rubber It can be seen that 40 and the second L-shaped structure 50 are arranged in a straight (-) shape. The hollow formed in the center of the first fin-shaped structure 30 is a screw hole for receiving the height adjustment bolt.

5 is a structural diagram of the first fin-shaped structure 30 of the damping rubber according to the first embodiment of the present invention, the first vertical plate 31 and the horizontal plate 32 and the second vertical plate 33 ), You can see the process of forming the cross-section of the c-shaped.

FIG. 6 is a plan view of a vibration damping rubber according to a second embodiment of the present invention, in which two L-shaped structures 60 and 90 and rubbers 70 and 80 are further formed in the z direction when compared with the first embodiment. Structure, when viewed from above, the first L-shaped structure 10, the first rubber 20, the second k-type structure 30a, the second rubber 40 and the second L-shaped structure 50 and the third It can be seen that the L-shaped structure 60, the third rubber 70, the second fin-shaped structure 30a, the fourth rubber 80 and the fourth L-shaped structure 90 are arranged in a cross (+) shape. Can be.

The third L-shaped structure 60 and the fourth L-shaped structure 90 are also composed of horizontal plates 61 and 91 having a length a and vertical plates 62 and 92 having a height b, respectively. Form.

FIG. 7 is a structural diagram of a second V-type structure of vibration damping rubber according to the second embodiment of the present invention. The second V-type structure 30a is in the form of a cube with an open base, and the first vertical plate 31. ), The horizontal plate 32, the second vertical plate 33, the third vertical plate 34 and the fourth vertical plate 35 is connected can be seen that the cross-section process to form a c-shape.

In the case of the first embodiment, if two rubbers 20 and 40 are coupled to the first fin-shaped structure 30 in the center, the four rubbers 20, 40, 70 and 80 in the second embodiment are centered. All four surfaces of the second V-type structure 30a are coupled to each other.

That is, in the case of the second embodiment, the shape, size, and coupling method of the rubber are the same as those of the first embodiment, but only the shape of the central second fin structure 30a is changed.

In the first embodiment, the structural stability is easily broken when a load or a moment is applied in the z direction, but in the second embodiment, the structural stability is increased due to resistance to rotation and load in both the x direction and the z direction.

8 is a cross-sectional view of the damping rubber according to the third or fourth embodiment of the present invention, and has a structure symmetrical with the damping rubber of the first and second embodiments.

In the case of the third embodiment or the fourth embodiment, since the vibration damping rubbers of the first and second embodiments are reversed, an inverted L type structure is used instead of the L type structure, and └┘ type structure is used instead of the L type structure. In contrast to the first and second embodiments, the lower horizontal plate of the ┘-type structure is in contact with the bottom surface, and the rubber is inclined toward the inverted L-type structure to form a structure in which the inverted L-type structure is floated. Having a deformation space equal to the inclined height of the rubber is the same as in the first and second embodiments.

In the case of the third embodiment or the fourth embodiment, there is an advantage in that the first and second embodiments can utilize a space formed under the U-shaped structure. For example, a support plate can be inserted to lower the overall height of the damping rubber.

The vibration damping rubber of the present invention has a high damping ratio (13 to 15%) compared to the conventional rubber, and has excellent vibration damping performance, easy to design a load resistance against static load, and has excellent mechanical energy absorption due to large deformation. Wide application is expected, and the actual floor shock sound insulation performance test (heavy shock sound test), as a result of 43 dB (weight shock sound class 2 equivalent) confirmed the excellent performance as a rubber for impact shock reduction.

The vibration damping rubber according to the present invention maintains rigidity through shear deformation, but can be largely deformed, which is advantageous for relieving the initial impact force, and has a high damping ratio compared to the conventional rubber, which has excellent vibration damping performance, and is also easy to design load resistance against static load. Due to this large deformation, it is advantageous for mechanical energy absorption.

Claims (12)

An L-shaped structure consisting of a horizontal plate and a vertical plate, a V-shaped structure consisting of two vertical plates and an upper horizontal plate, and rubber. The two L-shaped structures are arranged so as to face each other with the center of the curved structure disposed at the center, and the two rubbers are coupled to each vertical plate of the curved structure at the same time as the two rubbers are joined to the vertical plates of the respective L-shaped structures. Vibration-insulating rubber for vibration isolation. An L-shaped structure consisting of a horizontal plate and a vertical plate, a k-shaped structure consisting of four vertical plates and an upper horizontal plate, and rubber. Four L-shaped structures are arranged so that two pairs face each other with the center of the curved structure arranged at the center, and the four rubbers are bonded to the vertical plates of each L-shaped structure and to each vertical plate of the curved structure. Vibration-insulating rubber for vibration isolation. The vibration damping rubber according to claim 1 or 2, wherein the horizontal plate of the L-shaped structure is in contact with the bottom surface, and the rubber is inclined toward the V-shaped structure to form a floating structure of the V-shaped structure. The vibration damping rubber for vibration insulation according to claim 3, characterized in that it has a deformation space equal to the inclined height of the rubber. The vibration damping rubber for vibration insulation according to claim 3, wherein the inclined portion of the rubber has an arc shape concave toward the center of the rubber. The vibration damping rubber for vibration insulation according to claim 1 or 2, wherein the L-shaped structure and the K-shaped structure are made of metal, plastic or wood. Inverted L-shaped structure consisting of a horizontal plate and a vertical plate, └┘ structure consisting of two vertical plates and a lower horizontal plate, and rubber The two inverted L-shaped structures are arranged to face each other around the └┘-shaped structure placed in the center, and the two rubbers are bonded to the vertical plates of each inverted-L structure, and to each vertical plate of the └┘-shaped structure. Vibration-insulating rubber for vibration isolation. Inverted L-shaped structure consisting of a horizontal plate and a vertical plate, └┘ structure consisting of four vertical plates and a lower horizontal plate, and rubber The four inverted L-shaped structures are arranged so as to face each other two pairs around the └┘-shaped structure placed in the center, and the four rubbers are joined to the vertical plates of each inverted L-shaped structure and each vertical plate of the └┘-shaped structure Vibration insulation damping rubber, characterized in that coupled to. The vibration damping rubber for vibration insulation according to claim 7 or 8, wherein the horizontal plate of the ┘-type structure is in contact with the bottom surface, and the rubber is inclined toward the inverted L-type structure to form a reverse L-type structure. . The vibration damping rubber for vibration insulation according to claim 9, wherein the vibration isolation rubber has a deformation space equal to the inclined height of the rubber. The vibration damping rubber for vibration insulation according to claim 9, wherein the inclined portion of the rubber has an arc shape concave toward the center of the rubber. The vibration damping rubber for vibration insulation according to claim 7 or 8, wherein the reverse L-shaped structure and the └ structure are made of metal, plastic or wood.

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