JP2007010094A - Coil spring and vibration absorbing device using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coil spring having simple construction for preventing surging without impairing the specific spring property of the coil spring, and to provide a vibration absorbing device using the same. <P>SOLUTION: The coil spring 16 comprises a tubular body 14 formed of a rubber elastic material and arranged in close contact with the outer periphery of a metal coil spring body 12, and having a length smaller than the total length of the coil spring body 12 in the expanding direction. The vibration absorbing device comprises the plurality of coil springs 16 arranged in parallel between an upper frame 26 on which a vibration absorbed object is placed and a lower frame 28 which is placed on a floor surface. Damping operation is performed by the tubular body 14 without impairing the specific spring property of the coil spring 16, resulting in simple construction for preventing surging. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention particularly relates to a coil spring with a surging prevention function and a vibration isolator using the same, which is suitable for vibration isolating support of industrial equipment that generates high-frequency vibrations such as refrigerators, generators, large cooling towers, transformers, etc. About.

  The coil spring made of metal has the advantage that the load-bearing range is large because it is durable and can support a large load. However, it generates a resonance phenomenon called surging as shown in FIG. May degrade performance. The frequency at which surging occurs depends on the shape of the coil spring and the like, but often occurs in a high frequency region of 100 Hz (hertz) or higher. For this reason, a coil spring is used for industrial equipment that generates high-frequency vibration, and a vibration isolator without a surging prevention function cannot be applied.

In order to prevent surging of the coil spring, a method of adding a damping material to the coil spring has been conventionally used. For example, (1) there is a compression coil spring in which a rubber elastic body or a viscoelastic body is disposed on the outer periphery of a coil spring, and these elastic bodies are always in contact with the coil spring (see Patent Document 1). In addition, there is (2) a vibration isolator formed by covering a coil spring with a rubber elastic material over its entire length (see Patent Document 2). (3) The coil spring is housed in the upper case and the lower case that are overlapped, and the lower case is immersed in a viscoelastic agent such as gel in the lower case. There is a device (see Patent Document 3).
JP-A-8-210439 JP-A-8-121533 JP-A-8-121532

By the way, the above technique has the following problems to be solved.
The inner and outer diameters of the coil spring change according to the displacement in the expansion / contraction direction. That is, in the compressed state, both the outer diameter and the inner diameter increase. Therefore, the structure for applying a damping force to the coil spring needs to follow the change in the outer diameter and the like.

  In the case of the compression coil spring of the above (1), the rubber elastic body or viscoelastic body is constantly pressed against the outer periphery of the coil spring by a leaf spring or the like to cope with changes in the outer diameter of the coil spring. . However, it has a complicated structure including a leaf spring and a member that supports the leaf spring.

  Further, in the case of the vibration isolator (2) described above, changes in the outer diameter and the like of the coil spring are accommodated by the elasticity of the rubber elastic material positioned between the coil spring lines. However, the rubber elastic material hinders the flexible compression action of the coil spring and impairs the spring characteristics unique to the coil spring. Further, the space between the coil springs becomes narrow due to compression deformation, and an excessive stress is generated in the sandwiched rubber elastic material.

  In the case of the vibration isolator (3) described above, the surging of the coil spring is prevented by the gel-like viscoelastic agent, but there is a problem that the structure for accommodating the gel-like viscoelastic agent becomes complicated. .

  The present invention has been made paying attention to the above points, and provides a coil spring capable of preventing surging with a simple structure without impairing the spring characteristics unique to the coil spring, and a vibration isolator using the same. Objective.

In each embodiment of the present invention, the above-described problems are solved by the following configurations.
<Configuration 1>
A coil comprising a rubber-like elastic material, and a tubular body having a length shorter than the total length of the coil spring body in the expansion / contraction direction is slidably adhered to the outer periphery of the metal coil spring body. spring.

  Since the tubular body provides a damping action without impairing the spring characteristics unique to the coil spring, surging can be prevented with a simple structure. Moreover, since the tubular body is not bonded to the coil spring body, stress concentration on a part of the tubular body is avoided. In addition, metal fittings for attaching the tubular body are unnecessary, and cost reduction can be expected.

<Configuration 2>
The coil spring according to Configuration 1, wherein the tubular body is a heat-shrinkable tube.

  Since the tubular body is thermally contracted and adheres along the curved surface of the outer peripheral surface of the coil spring main body, the tubular body is always in contact with the coil spring main body and exhibits a stable damping effect.

<Configuration 3>
The coil spring according to Configuration 1 or 2, wherein the tubular body has a length of 2/3 or less and 1/3 or more of the total length of the coil spring main body in the expansion / contraction direction.

  There is no need to provide a tubular body over the entire length of the coil spring in the expansion / contraction direction. What is necessary is just to adjust the material and length of a tubular body suitably according to the size etc. of a coil spring main body.

<Configuration 4>
The coil spring according to Configuration 3, wherein a lower part of the coil spring body is covered with the tubular body, and a gel-like damping agent is accommodated in the tubular body.

  The damping performance is further improved.

<Configuration 5>
A tubular body made of a rubber-like elastic material is slid on a part of the outer periphery of a metal coil spring body between an upper frame on which an object for vibration isolation is placed and a lower frame placed on the floor surface. A vibration isolator having a plurality of coil springs arranged in close contact with each other.

  A vibration isolator having a simple configuration can be provided. The combination of the coil spring body and the tubular body can be easily configured according to the vibration proof specification, and maintenance such as replacement of a failed part is easy.

<Configuration 6>
6. The vibration isolator according to claim 5, wherein the coil spring is disposed on the lower frame through a lower cover, and a gel-like damping agent is accommodated in the lower cover.

  The damping performance is further improved.

  Hereinafter, embodiments of the present invention will be described in detail for each example.

FIG. 1 is a cross-sectional view showing a coil spring of the first embodiment.
A coil spring 16 shown in FIG. 1 includes a metal coil spring main body 12 and a tubular body 14 made of a rubber-like elastic material, and the tubular body 14 is disposed on the outer circumference of the coil spring main body 12 forming a cylindrical shape. Is.

  The tubular body 14 has a length shorter than the entire length of the coil spring body 12 in the expansion / contraction direction, and is in close contact with the outer periphery of the coil spring body 12. The tubular body 14 is made of a heat-shrinkable tube, and is thermally contracted to be in close contact with the curved surface of the outer peripheral surface of the coil spring main body 12, and is always in slidable contact with the coil spring main body 12.

  The tubular body 14 has an axial length that is less than two-thirds or less than one-third of the total length of the coil spring body 12, and includes butyl rubber, EPDM (Ethylene Propylene). Diene Methylene Linkage), chloroprene rubber, natural rubber, silicone rubber, butadiene rubber and the like are preferably selected from rubber materials having relatively low rigidity. That is, the tubular body 14 does not need to be provided over the entire length of the coil spring main body 12 in the expansion / contraction direction, and the material and the axial length are appropriately determined according to the size of the coil spring main body 12 and the like.

  In use, the coil spring 16 configured in this way is installed and attached between the lower plate 18 and the upper frame 20, for example. Reference numeral 22 denotes an annular spring seat that comes into contact with the end of the coil spring body 12.

  When vibration is generated in the coil spring body 12, sliding friction occurs between the coil spring body 12 and the tubular body 14, or an action of attenuating the vibration of the coil spring body 12 due to bending deformation of the tubular body 14 occurs.

FIG. 7 is a diagram showing the relationship between the resonance magnification and the frequency when vibration is prevented by the coil spring 16 of the first embodiment.
According to this coil spring 16, as shown in FIG. 7, the surging phenomenon as shown in FIG. 6 does not occur, and the spring characteristics peculiar to the coil spring are not impaired.

FIG. 2 is a cross-sectional view showing the coil spring of the second embodiment, and the same reference numerals are given to the portions common to FIG.
In this coil spring, a gel-like damping agent 24 is accommodated in a tubular body 14 of a coil spring having the same configuration as that of the coil spring 16 of FIG. The lower end portion of the tubular body 14 is in close contact with the lower plate 18 so that the gel-like damping agent 24 does not leak outside. As the material for the gel-like damping agent 24, silicone gel, urethane gel, or the like is preferable because it exhibits an appropriate damping effect.
According to the coil spring of the second embodiment, the damping performance can be further improved by accommodating the gel-like damping agent 24.

3 is a cross-sectional view showing a vibration isolator of Example 3, FIG. 4 is a plan view thereof, FIG. 5 is a front view thereof, and portions common to FIG.
In these drawings, the vibration isolator according to the third embodiment has four coil springs having the same configuration as that of the coil spring 16 in FIG. 1 mounted on an upper frame 26 on which a vibration isolation object is placed and a floor surface. The lower frame 28 is set. That is, four units are formed by slidably and closely arranging a tubular body 14 made of a rubber-like elastic material on a part of the outer periphery of the metal coil spring main body 12 between the upper frame 26 and the lower frame 28. The coil spring is disposed.

  The four coil springs are arranged in parallel on the lower frame 28 via a container-like lower cover 34 with an appropriate interval, and in the lower cover 34, silicone gel, urethane gel, etc. A gel-like damping agent 24 is accommodated. The lower end portion of the tubular body 14 floats from the bottom surface in the lower cover 34 so that the gel-like damping agent 24 contacts the inner peripheral surface of the tubular body 14.

Although not shown, the lower end portion of the tubular body 14 is brought into close contact with the bottom surface in the lower cover 34 so that the gel-like damping agent 24 contacts only the outer peripheral surface of the tubular body 14 so that the outer peripheral surface of the tubular body 14 is a gel. You may make it press always by the shape attenuation agent 24. FIG.
If comprised in this way, the tubular body 14 will always be closely_contact | adhered to the outer peripheral surface of the coil spring main body 12 with the pressing force of the gel-like attenuation agent 24, and moderate damping force will be obtained when a vibration generate | occur | produces in the coil spring main body 12. Can be.

  The upper frame 26 and the lower frame 28 are detachably connected by a stopper bolt 32. By disassembling the upper frame 26 and the lower frame 28, the coil spring body 12 and the tubular body 14 can be easily attached or replaced. In addition, a sound absorbing effect can be achieved by sticking the rubber pad 30 on the bottom surface of the lower frame 28.

  According to the present invention, a coil spring type vibration isolator having a simple configuration as shown in FIG. 3 can be provided. Further, the combination of the coil spring main body 12 and the tubular body 14 can be easily configured in accordance with the vibration proof specification, and maintenance such as replacement of a failed part is easy.

3 is a cross-sectional view showing a coil spring of Example 1. FIG. It is sectional drawing which shows the coil spring of Example 2. FIG. It is sectional drawing which shows the vibration isolator of Example 3. It is a top view of the vibration isolator. It is a front view of the vibration isolator. It is a diagram which shows the relationship between the resonance magnification and frequency at the time of performing vibration isolation only with a coil spring. It is a diagram which shows the relationship between the resonance magnification at the time of performing vibration proof with the coil spring shown in FIG. 1, and a frequency.

Explanation of symbols

12 Coil spring body 14 Tubular body 16 Coil spring 18 Lower plate 20 Upper frame 22 Spring seat 24 Gel-like damping agent 26 Upper frame 28 Lower frame 30 Rubber pad 32 Stopper bolt 34 Lower cover

Claims (6)

  A coil comprising a rubber-like elastic material and a tubular body having a length shorter than the overall length of the coil spring body in the expansion / contraction direction is slidably disposed on the outer periphery of a metal coil spring body. spring. The coil spring according to claim 1, wherein
A coil spring, wherein the tubular body is a heat-shrinkable tube. The coil spring according to claim 1 or 2,
The coil spring according to claim 1, wherein the tubular body has a length of 2/3 or less and 1/3 or more of the total length of the coil spring body in the expansion / contraction direction. In the coil spring in any one of Claims 1-3,
A coil spring characterized in that a lower part of the coil spring body is covered with the tubular body, and a gel-like damping agent is accommodated in the tubular body.   A tubular body made of a rubber-like elastic material is slid on a part of the outer periphery of a metal coil spring body between an upper frame on which an object for vibration isolation is placed and a lower frame placed on the floor surface. A vibration isolator having a plurality of coil springs arranged in close contact with each other. The vibration isolator according to claim 5,
The coil spring is disposed on the lower frame via a lower cover,
A vibration isolator comprising a gel-like damping agent accommodated in the lower cover.

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