KR20060058233A - Trembling disturbing structure of out side mirror of an automobile - Google Patents

Abstract

The present invention relates to an anti-shake structure of an outside mirror of a vehicle, wherein two spring members are mounted on an outside mirror holder in a diagonal position farthest from a center of an actuator axis located at the center of the mirror holder. The outside mirror's anti-shake structure which improves the mirror's vibration performance by transmitting the high frequency vibration generated in the mirror frame to the mirror holder by making the shape of the upper contact part in contact with the mirror frame of the spring member to be a flat surface for a certain period. .

Description

Trembling disturbing structure of out side mirror of an automobile

1A to 1D are views illustrating a binding structure of a conventional outside mirror;

2 is a graph showing a change in the vibration angle according to the vibration frequency band applied to the conventional outside mirror;

3A is a perspective view illustrating a state in which a spring member is attached on a mirror holder according to the present invention;

3B is a cross-sectional view showing a contact state between the spring member and the mirror frame shown in FIG. 3A;

4 is a graph illustrating a change in vibration acceleration G according to a vibration frequency applied to an outside mirror.

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

10 mirror outer case 20 mirror frame

30,50: Mirror holder 31,53,55: Spring member

40: mirror 70: actuator

60: actuator shaft 100: outside mirror

The present invention relates to an outside mirror anti-shake structure, and more particularly, to an anti-shake structure of a vehicle outside mirror which minimizes the shake of the outside mirror by installing a double spring member on the mirror holder.

In general, the outside mirror of the vehicle should satisfy the vibration performance during driving. In the development of the product, the vibration test and the noise test for checking the vibration performance are set as test items to improve the quality.

Among the test items, the noise test of the mirror gets an early satisfactory state, but the vibration test is still not easily improved, and various methods have been tried to improve the shaking state, but the satisfactory state cannot be obtained.

1A to 1D are views illustrating a binding structure of a conventional outside mirror.

Figure 1a is a perspective view showing the appearance of the outside mirror,

1B is a cross-sectional view taken along the line A-A of FIG. 1A,

Figure 1c is a detailed view of the portion where the spring member of Figure 1b is located,

1D is a perspective view of a conventional outside mirror holder.

In the conventional outside mirror 100, as shown in FIG. 1A, the mirror case 10 is positioned outside and the inside of the mirror case 10 of the outside mirror 100 is illustrated in FIG. 1B. A series of components that form the interior are mounted.                         

Referring to FIG. 1B, the mirror 40 is positioned spaced apart on the mirror holder 30, and an actuator connecting shaft 60 whose one end is connected to the actuator 50 is attached to the rear of the mirror 40 so that the mirror ( The installation angle of 40) can be adjusted.

A single spring member 31 is provided at one side of the mirror holder 30, and the spring member 31 protrudes a predetermined length to the upper portion of the mirror holder 30 and contacts the mirror frame 20 in front of the mirror holder 30. It is supposed to be. At this time, between the spring member 31 and the mirror frame 20 is in point contact with each other in the circular projection (31a) formed on the front end of the spring member (31).

In the conventional outside mirror binding structure as described above, the spring member 31 serves to improve the vibration of the mirror 40 by transmitting the vibration of the high frequency generated in the mirror frame 20 to the mirror holder 30 side. Do it. That is, as the frequency generated by the mirror 40 increases, the degree of vibration of the observed mirror decreases, so that a separate spring member 31 is provided in the mirror frame 20 which generates vibrations of high frequency relative to the mirror 40. By connecting the high frequency vibration is transmitted to the mirror 40 well.

Therefore, the conventional spring member 31 is formed of a single spring member 31 to transmit vibration well, and has a structure that has a certain rigidity that does not move well even when pushed by hand.

In addition, the spring member 31 is to apply a continuous force in the direction of the arrow (Fig. 1c), that is, the right direction shown with respect to the mirror frame 20, whereby the spring member 31 is a mirror frame 20 While maintaining close contact with the spring member 31 by the elasticity of the self at all times with the same force, serves to fix the mirror 40 to the mirror frame 20 to be strong against vibration.

On the other hand, Figure 2a is a graph showing the results of the shaking test on the conventional outside mirror described above, a change in the vibration angle appearing in accordance with the frequency band applied to the mirror.

As can be seen from the results shown in the figure, the maximum resonance phenomenon is shown at two places of the frequency 60Hz and 87 Hz, which shows a large difference compared to the case of a single mirror point (see Fig. 2b) have.

That is, in the conventional outside mirror, tremor does not occur because it is strong to a small force to some extent, but when the vehicle runs at a high speed of a certain speed or more, for example, 140 Km / h or more, the outside mirror tremors appear more large, There was a problem in that the tremor performance of the outside mirror greatly decreased during driving.

Accordingly, an object of the present invention is to provide a shake preventing structure of an outside mirror, which improves the shaking phenomenon of the outside mirror by improving the binding structure of the spring member to be bonded on the mirror holder in order to solve the conventional problems as described above. It is done.

The anti-shake structure of the outside mirror of the present invention for achieving the above object is a mirror, adjacent to the mirror

A mirror holder, a spring member provided on one side of the mirror holder, a mirror frame in contact with an upper end of the spring member, a mirror outer case positioned outside the mirror frame, and one end connected to a rear side of the mirror. In the anti-shake structure of the outside mirror including an actuator connecting shaft for adjusting the position of the mirror,

At least one spring member is installed on the mirror holder, each of which is installed in a diagonal position at a distance from the actuator shaft located at the center of the mirror holder, to minimize vibration of the mirror. do.

Preferably, two spring members are installed at both edges of the mirror holder at a distance from the actuator shaft.

In addition, the spring member is preferably such that the contact portion in contact with the mirror frame of the upper end is formed in a flat surface for a certain period so that the line contact is made.

Hereinafter, a preferred embodiment of the anti-shake structure of the outside mirror according to the present invention with reference to the accompanying drawings will be described in detail.

3A is a perspective view illustrating a state in which a spring member is attached on an outside mirror holder according to the present invention;

3B is a cross-sectional view showing a contact state between the spring member and the mirror frame shown in FIG. 3A.

As shown, two spring members 53 and 55 are attached to the outside mirror holder 50 according to the present invention, and the positions at which the two spring members 53 and 55 are installed are located in the actuator shaft 60. ) Is positioned at a distance in a diagonal direction, for example, near both edges of the mirror holder 50.                     

That is, the vibration of the mirror holder 50 can be more effectively reduced by keeping the spring members 53 and 55 away from the actuator shaft 60 located in the center of the mirror holder 50.

In addition, the spring member (53, 55) of the present invention, as shown in Figure 3b, the flat surface is formed over a certain period (length) of the portion (53a or 55a) in contact with the mirror frame 20, the two components It is designed to have a structure in which line contact is made between them.

That is, the upper contact portions 53a, 55a of the spring members 53, 55 in contact with the mirror frame portion 20 are formed in a trapezoidal shape in which line contact is made in a conventional circular protrusion which provides a point contact structure. Accordingly, the line contact between the spring members 53 and 55 and the mirror frame 20 can efficiently transmit vibrations of high frequency generated in the mirror frame 20 to the mirror holder 30 through the spring members 53 and 55. It becomes possible.

In addition, the spring members 53 and 55 of the present invention are elastic enough to be easily moved when pushed by hand, and are relatively lightweight spring members compared to a single single spring member, and both side edge portions of the mirror holder 30 are provided. Since two are installed in the vicinity, the contact area with the mirror frame 20 is widened to transmit the high frequency vibration generated in the mirror frame 20 to the mirror holder 20 better.

Whether the shaking performance of the mirror 40 is improved by the installation of the plurality of spring members 31 can be clearly seen through a graph shown through the following test.

4 is a graph illustrating a change in vibration acceleration G according to a vibration frequency applied to an outside mirror.                     

In the figure, the graph shown by the dotted line is the case of the anti-shake structure of the conventional outside mirror, and the graph shown by the solid line shows the case of the anti-shake structure of the outside mirror of the present invention, respectively.

As can be seen from the graph, in the conventional case in which one spring member is installed, the maximum vibration acceleration reaches 0.22, but in the present invention in which two spring members are installed in duplicate, the magnitude of the maximum vibration acceleration is 0.13. It can be seen that only the magnitude of the amplitude is significantly different.

Through the above experiment, it can be seen that the vibration performance of the outside mirror is greatly improved under the outside mirror anti-shake structure of the present invention in which the double spring members 53 and 55 are mounted on the mirror holder 50.

As described above, the anti-shake structure of the outside mirror according to the present invention double mounts two spring members at a position in a diagonal direction far from the actuator axis on the mirror holder, and contacts the side mirror frame. The shape of the contact portion is a structure in which the line contact is made, and the vibration of the high frequency generated in the mirror frame is transmitted to the mirror holder side, whereby the vibration performance of the outside mirror can be improved.

Claims (3)

A mirror, a mirror holder adjacent to the mirror, a spring member provided on one side on the mirror holder, a mirror frame in contact with an upper end of the spring member, a mirror outer case located outside the mirror frame, and a rear surface of the mirror In the anti-shake structure of the outside mirror including an actuator connecting shaft to which one end is connected to the side to adjust the position of the mirror, At least one spring member is installed on the mirror holder, the anti-shake structure of the outside mirror, characterized in that installed in a diagonal position at a distance from the actuator axis located in the center of the mirror holder. The method of claim 1, The spring member is an anti-shake structure of the outside mirror, characterized in that the two installed on both side corners on the mirror holder. The method according to claim 1 or 2, The spring member is an anti-shake structure of an outside mirror, characterized in that the contact portion which is in contact with the mirror frame of the upper end is formed in a flat surface for a predetermined period so that the line contact is made.

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