JPS63308242A - Vibration isolating device - Google Patents

Abstract

PURPOSE:To develop an excellent attenuation characteristic, and to provide with a high vibration isolation performance in which the temperature dependency of the attenuation characteristic has been improved, and further to simplify the structure, by mixing, in a viscous fluid, at least a kind of resin whose glass- transition temperature is within the range of working temperatures. CONSTITUTION:Both ends of a cylindrical rubber body 2 are closed with fittings 4 and 6 to fill a prescribed viscous fluid 8 in the closed fluid housing space, and a prescribed resin 10 whose glass-transition temperature is within the range of working temperatures is mixed in the viscous fluid. Thus, an excellent attenuation characteristic can be developed, and a high vibration isolation performance in which the temperature dependency of the attenuation characteristic has been improved can be provided. Since the vibration attenuation performance can be improved only by mixing a prescribed resin, it is not necessary to provide a special mechanism. Accordingly, it is possible to simplify the structure as a vibration isolation system, enabling it to be applicable to even small size products, and further enabling the manufacturing man-hour and the number of parts to be reduced and an inexpensive system to be constituted.

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field) The present invention relates to a vibration isolating device, particularly for use in audio equipment, precision measuring equipment, etc., which exhibits a vibration damping effect by the resistance force mainly caused by the viscosity of viscous fluid. The present invention relates to a viscous fluid-filled vibration isolating device that is suitably used.

(Background Art) Conventionally, audio equipment such as video tape recorders and compact disc players, as well as various precision measuring instruments, have had the problem that their performance is greatly impaired by vibration input from the outside. Various types of vibration isolators and vibration isolators have been proposed, but among them, the Japanese Patent Laid-Open No. 6
As seen in JP-A No. 1-189336 and JP-A-61-201946, a predetermined viscous fluid such as silicone oil is sealed in a deformable container such as a rubber bag or a rubber cylinder, and A vibration isolating device having a structure for supporting the above-mentioned equipment has been disclosed. In this kind of viscous fluid-filled vibration isolator, the structure is designed to generate a flow in the sealed fluid when vibration is input, and at that time, the resistance force generated due to the viscosity of the sealed fluid, etc. is configured to provide a vibration damping force.

By the way, relatively high viscosity mineral oil, silicone oil, etc. have been used as the viscous fluid, in other words, the sealed liquid, in this type of vibration isolating device.
Even with the above-mentioned viscous fluid-filled vibration isolators, their vibration isolation performance is insufficient for automotive applications that are used under harsher conditions or equipment that requires higher precision. In addition, there are inherent problems such as temperature dependence in its attenuation characteristics.

(Problem to be Solved) The present invention has been made against this background, and its purpose is to effectively improve the damping characteristics and to advantageously alleviate its temperature dependence. It is an object of the present invention to provide a viscous fluid-filled vibration isolating device having a high vibration insulating performance.

(Structure of the Invention) In order to achieve the above object, the present invention includes a predetermined viscous fluid sealed in a deformable container,
In a vibration isolating device that is interposed between two members to which vibrations are transmitted, and is designed to exert a vibration damping effect by the resistance force mainly caused by the viscosity of the viscous fluid, the viscous fluid has a glass transition point. The gist thereof is that at least one resin within the operating temperature range is mixed.

(Specific Structure/Examples of the Invention) Hereinafter, the structure of the present invention and its embodiments will be specifically described with reference to the drawings.

First, FIG. 1 shows a longitudinal cross-sectional view of an example of the vibration isolating device according to the present invention, in which 2 is a cylindrical rubber body that is narrowed at the center and can expand laterally. By closing both ends of this cylindrical rubber body 2 with fittings 4 and 6, a sealed fluid storage space is formed inside, and a predetermined viscosity is formed in this fluid storage space. A fluid 8 is sealed therein. Moreover, a predetermined resin 10 whose glass transition point (Tg) is within the operating temperature range is mixed into the sealed viscous fluid 8.

A device having such a structure is interposed between two members to which vibrations are transmitted, respectively, via mounting brackets 4 and 6 located at the top and bottom in the figure, and is mainly isolated in the vertical direction. When the vibrations to be generated are applied manually, the enclosed viscous fluid 8 causes the cylindrical rubber body 2 to bulge and deform laterally, thereby achieving the desired purpose based on the flow induced in the viscous fluid 8. This results in effective vibration isolation performance. Here, in order to make the flow of the viscous fluid 8 effective, the mounting portion 6a disposed at the center of one of the mounting brackets 6 is located at a predetermined position on the side of the other mounting bracket 4 within the fluid storage space. It is provided with a protruding length.

By the way, in this type of viscous fluid-filled vibration isolating device, the vibration damping force is generally considered to be mainly a resistance force due to the viscosity of the fluid, etc. , silicone oil, etc. have been considered, but these have not yet demonstrated sufficient performance.

For this reason, the present inventors blended a resin such as a solid polymer or a liquid polymer that has a glass transition point within the operating temperature range into the viscous fluid to be enclosed, and oscillated the behavior of the resin at the glass transition point. We thought that it could be used to increase insulation performance, and as a result of various studies, we discovered that by incorporating such a resin, damping characteristics can be effectively improved and its temperature dependence can be significantly improved. be.

In other words, using a vibration isolating device having the structure as shown in FIG. 1, and varying the blending amounts of the viscous fluid and predetermined resin sealed therein as shown in Table 1 below, the vibration isolation device was tested at various temperatures. The results of investigating the effects of blending such resins are shown in FIGS. 2 and 3.

Table 1 Mixing ratio (volume %) (Note) Silicone oil: KF96 manufactured by Shin-Etsu Chemical Co., Ltd. (500
00cSt) Liquid NBR: Nipolar acrylic resin manufactured by Nippon Zeon Co., Ltd.: Dianal BR102 manufactured by Mitsubishi Rayon Co., Ltd. In each of these characteristic evaluations, the rubber material constituting the cylindrical rubber body 2 of the apparatus shown in FIG. As, hardness (J
Is-ni-6301 spring hardness test; A type) 40
A vibration isolating device to be evaluated was prepared by using isobutylene/isoprene rubber (CIIR) and filling the fluid containing space with various mixed fluids as shown in Table 1. Then, the loss coefficient and Young's modulus of the obtained vibration isolating device were determined using a dynamic viscoelasticity tester, and the damping characteristics and spring characteristics of each were evaluated.
As shown in FIGS. The measurement conditions were: vibration frequency: 30H, initial compression ratio: 10%, dynamic strain:
±20μ, measurement temperature range: -40°C to 80°C1 temperature increase rate = 1°C/min was adopted.

As is clear from the results shown in Figures 2 and 3,
Compared to Comparative Example A in which only silicone oil is sealed, the present invention example in which liquid NBR or acrylic resin having a secondary transition point in the operating temperature range of 40°C to 80°C is blended into silicone oil. Both devices C and D are 1
The devices of Examples C and D of the present invention have a large loss coefficient (η) and excellent damping characteristics, and have small temperature dependence compared to Comparative Example B in which only liquid NBR is sealed. Therefore, it becomes a practically good vibration isolating device. Furthermore, regarding the splash characteristics, no significant difference was observed between Comparative Examples A and B and Invention Examples C and D.

As mentioned above, the viscous fluid sealed in the vibration isolating device has a high kinematic viscosity at its operating temperature. Although fluids can be used, in cases where it is necessary to obtain the desired effect over a relatively wide temperature range, it is desirable to use silicone oil whose viscosity changes little with temperature. The effect can be further enhanced. The kinematic viscosity of such a viscous fluid is preferably at least 5000 centistokes or higher in order to obtain significant effects.

Furthermore, as the resin mixed into such a viscous fluid, any liquid or solid resin having a glass transition point (Tg) within the operating temperature range may be used as long as it does not have an adverse effect on the viscous fluid. For example, examples of liquid NBR equivalent to the above example include polymethyl acrylate (Tg: 0 to 3°C), polyvinyl acetate (
There are resins such as Tg: 28-30°C), and 6-nylon (Tg: 5
0°C), 6-row nylon (Tg: 47°C), and the like can be used.

In particular, in the present invention, at least two types of the above-mentioned resins are mixed into the viscous fluid, and each of the plurality of resins has a different glass transition point within the operating temperature range. is desirable, and by increasing the loss coefficient near the glass transition point of each of these plurality of resins, it is possible to advantageously realize better damping characteristics with less temperature dependence.

The amount of such resin mixed into the viscous fluid will be determined appropriately depending on the type of resin in order to obtain the desired performance, but generally the amount of the resin mixed into the viscous fluid will be 20 to 70% by volume. It will be made to exist. In addition, the form in which such resin is mixed is determined appropriately depending on the type of mixed resin, but in the case of a solid resin, it is mixed into a viscous fluid in the form of a powder. It happens.

By the way, the vibration isolating device according to the present invention can be used as it is, interposed between two members to which vibrations are transmitted, and used for vibration-proof support of one of the members to the other member. It is also possible to use it for anti-vibration support of a predetermined device (one member) in combination with a coil spring, etc., and one specific example of its application is the fourth
As shown in the figure.

That is, in the example shown in FIG. 4, the vibration isolating device according to the present invention is placed inside the coil spring 12, and the vibration isolating device of the coil spring 12 is placed between the mounting bracket 4 on the upper part and the support base 14. An elastic force is applied to the upper mounting bracket 4, and a predetermined device to be vibration-isolated is mounted on the upper mounting bracket 4. Such a coil spring 12
By adopting a structure in which both are used in combination, even more effective vibration-proofing effects can be obtained.

As described above, the vibration isolating device according to the present invention can be installed in various forms between two members to which vibrations to be vibration-isolated are transmitted, and the vibration isolating device according to the present invention has various configurations. However, the present invention is by no means limited to the specific examples described above, and various modifications and changes may be made based on the knowledge of those skilled in the art without departing from the spirit of the present invention.
It should be understood that modifications, improvements, etc. may be made, and that the present invention also includes such embodiments.

For example, the container in which the viscous fluid mixed with a predetermined resin is sealed may have any structure as long as its deformation can cause the viscous fluid contained therein to flow. In addition to the cylindrical structure shown in the example, there is no problem with a bag-like structure, a bellows-like structure, or a diaphragm structure. In addition to rubber materials, other elastic materials such as elastic plastics can also be used, and there is no problem even if the material is made of a general resin material.

(Effects of the Invention) As is clear from the above description, the viscous fluid-filled type vibration isolating device according to the present invention has a specific resin mixed in the viscous fluid to be filled, and as a result,
It exhibits excellent damping characteristics, and also has improved temperature dependence of the damping characteristics, providing high vibration insulation performance.

Vibration damping performance can be improved simply by mixing a specified resin into viscous fluid, and there is no need to provide a special mechanism for this purpose, so it has been used as a vibration isolation system for audio equipment, precision measurement equipment, etc. , the structure is simple and it can be applied to small products, and it is also possible to construct an inexpensive system with fewer manufacturing steps and fewer parts.

[Brief explanation of drawings]

FIG. 1 is a longitudinal cross-sectional view showing an example of a vibration isolating device according to the present invention, and FIGS. 2 and 3 are graphs showing the relationship between operating temperature, loss coefficient, and Young's modulus, respectively,
FIG. 4 is an explanatory cross-sectional view showing one specific application example of the vibration isolating device according to the present invention. 2: Cylindrical rubber body 4, 6: Mounting bracket 8: Viscous fluid 10: Resin 12: Coil spring 14: Support Heath Applicant: Tokai Rubber Industries, Ltd. Figure 1 Figure 2 L ("C)

Claims (5)

[Claims] (1) A predetermined viscous fluid is sealed in a deformable container and interposed between two members to which vibrations are transmitted, and the viscous fluid exhibits a vibration damping effect mainly due to the resistance force generated by the viscosity. A vibration isolating device characterized in that the viscous fluid contains at least one resin whose glass transition point falls within the operating temperature range. (2) The vibration isolating device according to claim 1, wherein the viscous fluid is silicone oil. (3) The vibration isolating device according to claim 2, wherein the silicone oil has a kinematic viscosity of 5000 centistokes or more. (4) The resin is present in the viscous fluid in an amount of 20 to 70% by volume.
The vibration isolating device according to any one of claims 1 to 3, wherein the vibration isolating device is mixed in a proportion of . (5) At least two types of resins are mixed in the viscous fluid, and each of the plurality of resins has a different glass transition point within the operating temperature range. The vibration isolating device according to any one of items 1 to 4.