KR100289440B1 - Dustproof Rubber for Refrigerator Compressor - Google Patents

Abstract

The present invention relates to a dustproof rubber for a refrigerator compressor to reduce the transmission of vibration generated in the compressor, the stand 40 extending from the base 20 penetrates the hollow portion of the dustproof rubber 10, the dustproof The upper portion 11 and the lower portion 12 of the hollow portion of the rubber 10 are in contact with the stand 40, and the hollow intermediate portion which is not in contact with the stand 40 is located in the inner grooves 13 and 15. The grooves 14 and 16 have a growth bar structure.

Description

Dustproof Rubber for Refrigerator Compressor

The present invention relates to a dustproof rubber for refrigerator compressor, and more particularly to a dustproof rubber for refrigerator compressor to reduce the transmission of vibration generated in the compressor.

As shown in FIG. 1, the vibration generated during the operation of the compressor is a base (refrigerator machine floor) 2 and a stand (e.g., a dustproof rubber 1) via a compressor ear mount (3). 4) to be transmitted to the entire door and the refrigerator, the shape of the anti-vibration rubber (1) is the same as Figure 1, when installed in the compressor, the existing anti-vibration rubber with a hardness of 60 is about 0.5 mm down. At this time, the upper part of the stand (3) extending from the base (2) and the upper part of the anti-vibration rubber (1) is designed to secure the anti-vibration rubber (1). The stand 4 penetrates the hollow portion at the center of the anti-vibration rubber 1.

Meanwhile, since the compressor of the refrigerator is reciprocating, vibration of about 60 Hz frequency is continuously generated, and the vibration generates vibration of other parts through parts connected to the compressor. In particular, the pipes of the connected parts can be reduced by self-damping, but the vibration coming out of the floor does not have self-damping, thereby generating noise as well as 'humid' vibration. For the purpose of preventing such a phenomenon, vibration is reduced by installing a dustproof rubber 1 suitable for the characteristics of a compressor between the bases 2. At this time, by the weight of the compressor, the anti-vibration rubber 1 is reduced in vibration in a state of falling about 0.5 mm.

Since the compressor of the refrigerator is a reciprocating type, the vibration locked in the horizontal direction is more problematic than the vibration in the vertical direction due to the eccentricity during the rotational movement of the motor. In addition, the vibration of the compressor is about 0.5 mm due to the weight of the vibration, which is usually favorable for vibration transmission as the vibration-proof rubber is soft or has a higher frequency than the natural frequency of the vibration-proof rubber. The softness of the rubber is usually managed by the material, but even the same material can be greatly different by its shape.

Fig. 2 shows a brief graph of the excitation frequency and the anti-vibration design. The responsiveness is the force transmitted to the floor / the force applied to the compressor and the resonance occurs when the vibration frequency / vibration-free rubber intrinsic frequency is 1. do. On the other hand, the Y value of the point where the excitation frequency meets the response curve becomes the transfer force to the floor. Therefore, the response should be designed in a region lower than 1, and the excitation frequency may be increased or the natural frequency of the anti-vibration rubber may be reduced. .

In the structure of the conventional anti-vibration rubber, the amount of vibration transmitted is largely adversely affecting the overall noise and strength of the refrigerator.

The present invention is to solve this conventional problem, to further reduce the force to be transmitted away from the frequency with the natural frequency of the anti-vibration rubber itself, while minimizing the contact area with the supported compressor base while the upper and lower parts An object of the present invention is to provide a dustproof rubber structure for a refrigerator compressor that can reduce vibration transmission and scattering through a base to support it.

In order to achieve the above object, in the anti-vibration rubber for refrigerator compressor of the present invention, in the anti-vibration rubber for refrigerator compressor in which the stand extending from the base passes through the hollow portion of the anti-vibration rubber, the anti-vibration rubber is hollow in contact with the stand. Upper and lower portions of; It is provided with a hollow intermediate portion that is not in contact with the stand, characterized in that the intermediate portion is formed in the shape of the jar.

1 is a cross-sectional view of a dustproof rubber for a conventional refrigerator compressor

Fig. 2 is a graph of excitation frequency and responsiveness by anti-vibration rubber

Figure 3 (a) (b) (c) is a graph showing the response function at the time of up, down, share, bending bending

Figure 4 is a graph of comparison of the vibration amount in the base in the conventional anti-vibration rubber and the anti-vibration rubber of the present invention

Fig. 5 is a graph showing a comparison of vibration amount in a door in the conventional anti-vibration rubber and the anti-vibration rubber of the present invention.

6 is a noise level comparison graph of the conventional anti-vibration rubber and the anti-vibration rubber of the present invention.

7 is a cross-sectional view of the dustproof rubber for a refrigerator compressor according to the present invention.

*** Explanation of symbols of main part of drawing ***

10: dustproof rubber 11: upper contact part

12: lower contact portion 13, 14, 15, 16: groove portion

20: base 30: ear mount

40: stand

In the anti-vibration rubber for refrigerator compressor of the present invention, as shown in Figure 7, the stand 40 extending from the base 20 passes through the hollow portion of the anti-vibration rubber 10, The upper portion 11 and the lower portion 12 of the hollow portion are in contact with the stand 40, and the hollow intermediate portion which is not in contact with the stand 40 is the inner groove 13, 15 and the outer groove 14 ( 16) it has a structure.

The portion of the upper part 11 of the anti-vibration rubber 10 that is in contact with the stand 40 is reduced compared to the prior art can reduce the amount transmitted through the stand 40, the lower part 12 of the anti-vibration rubber stand It is in contact with 40 to reduce the amount of dispersion.

In addition, since the middle portion of the anti-vibration rubber 10 has a bellows structure, its shape can be softened. In the case of such bellows structure, when a large amount of deformation is generated by the impact, a strong structure is produced when an impact occurs. As shown in Figure 7, the grooves 13, 14, 15, 16 of the anti-vibration rubber to form a space for absorbing vibration even after sagging by the weight of the pusher can increase the damping effect. . When an external shooting is applied, the space of the groove is attached, so the rigidity is increased, thereby protecting from an external shock.

The anti-vibration rubber of the present invention shows a more favorable trend in the transmission force during vibration analysis as the natural frequency changes. Figure 3, in the conventional anti-vibration rubber and the anti-vibration rubber of the present invention, the response function at the time of excitation, the vibration analysis after the deflection analysis (prestress analysis) by the weight of the compressor, the output of the vibration When compared to the reaction force (Reaction Force) according to the frequency from the bottom. At this time, the excitation was applied with up-down excitation (Y direction), shear excitation (X direction), bending excitation (squeaking excitation), and the response was made in each degree of freedom direction (6 types) at the bottom of the anti-vibration rubber. The frequency response of was obtained. 3 (a) and 2 (b) show response functions (Y-direction response / up-down, X-direction response / share excitation, Z-direction response / bending excitation) in only one direction where the magnitude of each response is large. When applying the same size excitation of the modified shape, the response in all directions as well as in the direction shown in FIG. 3 is reduced. At this time, the response of the existing anti-vibration rubber is a solid line, the response to the anti-vibration rubber of the present invention is shown by a dotted line, and the Y-axis of the response function of FIG. 3 represents a log scale, which is more than the difference shown in the actual picture.

The effect of the present invention through the experiment is that in addition to the existing base vibration in terms of vibration, the amount of guided vibration is reduced. Dispersion caused by this has been eliminated.

4 and 5 show the vibration test results of the conventional anti-vibration rubber and the anti-vibration rubber of the present invention, in the case of the anti-vibration rubber of the present invention shows a result that the vibration amount is significantly reduced.

On the other hand, in terms of noise, the front / rear noise was reduced by more than 5㏈ in the existing model, and the noise reduction effect was 0.5 ~ 1㏈ in the existing 500 liter model. Figure 6 shows the noise test results of the conventional anti-vibration rubber and the anti-vibration rubber of the present invention.

As described above, according to the present invention, by supporting the stand in the upper and lower parts of the anti-vibration rubber and having a bellows structure in the middle part, it is further separated from the frequency having its own natural frequency so as to minimize the transmitted force. By minimizing the contact area with the compressor base can be reduced vibration transmission and dispersion through the base.

Claims (4)

In the anti-vibration rubber for refrigerator compressor in which the stand extending from the base penetrates the hollow part of the anti-vibration rubber, the anti-vibration rubber has a hollow upper part and a lower part contacting the stand and a hollow middle part not contacting the stand. Dustproof rubber for refrigerator compressor, characterized in that The method of claim 1, The intermediate part has a bellows structure consisting of a plurality of grooves formed on the inside and a plurality of grooves formed on the outside of the dustproof rubber for a refrigerator compressor. In the anti-vibration rubber for refrigerator compressor, in which the stand extending from the base passes through the hollow portion of the anti-vibration rubber, the hollow intermediate portion, which is not in contact with the stand, comprises a plurality of grooves formed on the inside and a plurality of grooves formed on the outside. Dustproof rubber for refrigerator compressor, characterized in that it has a structure The method of claim 3, wherein The anti-vibration rubber, the anti-vibration rubber for refrigerator compressor, characterized in that it has a hollow upper and lower parts in contact with the stand