KR0155469B1 - Static testing method of cut-noise efficiency for weather strip of car door and apparatus for enforcing the same - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to a static test method for sound insulation efficiency of an automobile door weather strip and an execution apparatus thereof.

The present invention is to install a pressing member having a relative displacement in the left and right direction and the weather strip in the sealed space in order to switch from the dynamic test that causes the error to a static test without the error, the outside of the sealed space The relative distance between the weather strip and the pressing member and the vertical distance between the sound source are adjusted while the sound source is installed on the weather strip in such a manner that the sound source can be vertically displaced. .

In order to carry out the method, the present invention provides a weather strip, a fixing member for fixing the weather strip, a closed measuring box in which the fixing member is installed, and an amount of stretching and gap generation of the weather strip. A pressing member installed on the measuring box so as to be slidably movable, the internal volume meter installed inside the measuring box, the external volume meter installed outside the measuring box, and the vertical movement on the weather strip. It is equipped with an execution device consisting of a buzzer to be installed.

Description

Static test method of sound insulation efficiency of automobile door weather strip and its execution device

1 is an apparatus and a test principle thereof for the test of the present invention.

2 is a sample diagram for practicing the present invention.

3 is a diagram illustrating test conditions according to a sample.

(a) is the case of the first sample.

(b) is for the second sample.

* Explanation of symbols for main parts of the drawings

1: measuring box 2: weather strip

3: fixing member 4: pressing member

5: buzzer (sound source) 6: internal volume meter

7: external volume meter A: first sample

B: second sample

TECHNICAL FIELD The present invention relates to a static soundproofing efficiency test method for automobile weather strips and an execution apparatus thereof.

The door weather strip is attached to the door frame of the vehicle to perform the function of preventing wind, dust, rainwater, etc. from entering the room between the vehicle body.

Such a weather strip is a rubber material and usually has a hollow portion having a cross-sectional shape, and the shape of the weather strip varies widely, such as having a lip on the hollow portion side and having no lip.

In addition, this weather strip is a solid medium that propagates the wind noise generated during the vehicle driving in the room. The sound intensity through which the wind noise is transmitted to the room is basically different depending on the cross-sectional shape of the weather strip. It also appears differently depending on the driving conditions. In the above, the wind noise refers to noise that the driver hears as noise generated by friction between the vehicle body and the air flows into the room while the vehicle is driving at high speed.

If the sound intensity in the room is small under the same conditions, it can be said that the sound insulation efficiency of the weather strip is good.

In the related art, the decibel was measured using a sound level meter while driving a vehicle to test the sound insulation efficiency of the weather strip as described above.

Since this test method is performed in a dynamic state, it is difficult to obtain accurate data values because the measured values are different from each other due to the change in the wind direction and the wind speed, the state of the driving rod, and the state of the test vehicle.

It is an object of the present invention to overcome the conventional dynamic test method, in which the test conditions are different, so that accurate data values for the sound insulation efficiency of the weather strip cannot be obtained. It is to provide a test method and its execution device.

In order to achieve the above object, the present invention provides a pressing member having a relative displacement in a left and right direction with a weather strip to be treated on a sealed space, and a sound source can be vertically displaced on the weather strip outside the sealed space. By adjusting the relative distance between the weather strip and the pressing member and the vertical distance of the sound source, and configured to compare and measure the sound pressure change of the inside and outside of the sealed space.

In order to carry out the method, the present invention relates to a weather strip, a fixing member for fixing the weather strip, a closed measuring box in which the fixing member is installed, and an amount of elongation and gap between the weather strip. A pressing member installed on the measuring box so as to be slidably movable on the measuring box, an internal volume meter installed inside the measuring box, an external volume meter installed outside the measuring box, and vertically moving upward and downward on the weather strip. It is equipped with an execution device composed of a buzzer that is possibly installed.

A description with reference to the accompanying drawings.

1 shows an experimental apparatus and its principle for implementing the present invention.

Here, the weather strip 2 is installed on the sealed measuring box 1 in a form similar to a real vehicle.

That is, the fixing member 3 corresponding to the door frame of the vehicle is installed and the weather strip 2 is fixed to the fixing member 3, and the pressing member 4 corresponding to the roof side outer panel of the vehicle is mounted on the weather member. It is installed to be treated with the strip (2).

The pressing member 4 is movable left and right to have a relative distance f in relation to the weather strip 2.

Outside the measuring box 1, a buzzer 5 serving as a sound source is installed to move vertically on the weather strip 2. The buzzer 5 has a constant sound output value, for example, a sound pressure of 40 dB, and is installed so that the vertical distance s with the weather strip 2 is variably adjusted.

In addition, internal volume meters 6 and external volume meters 7 are provided inside and outside the measurement box 1, respectively. The internal volume meters 6 and 7 have a measuring range of 30 to 100 dB.

The external volume meter 7 is fixed to the outer surface of the measuring box 1, and the inner volume meter 6 is placed on the bottom of the inner surface of the measuring box 1.

The present invention variably adjusts the relative distances f and s when the buzzer 5, which is a sound source, transmits a constant sound output value by using the weather strip 2 as a sample having several different cross-sectional shapes with the test apparatus as described above. While measuring the sound pressure change in and out of the measuring box 1 on each of the variable points.

Of course, the sound pressure measurement value is based on the numerical values shown in the internal volume meter 6 and the external volume meter 7, in particular, in the apparatus for testing of the present invention to read the value of the internal volume meter 6, the pressing member ( 4) was made of transparent material to look inside the measuring box (1).

Accordingly, the sound pressure values received by the internal volume meter 6 and the external volume meter 7 on the above-described variable points are different from each other when compared with each other. The farther the sound source is, that is, the larger the vertical distance s, the measurement box. (1) The sound pressure inside and outside becomes small, and the smaller the relative distance f represented by the gap between the pressing member 4 and the weather strip 2, the smaller the sound pressure inside and outside the measuring box 1 becomes.

The difference in sound pressure as described above is due to general conditions, but in the present invention, when the cross-sectional shape of the weather strip 2 is given differently, the sound insulation efficiency of the weather strip 2 may be different, and it is compared with the sound pressure change. For this purpose, the method and results of testing two samples will be described below.

In the present invention, the first sample (A) has a lip on one side of the hollow part as shown in FIG. 2 (a), and the second sample (B) does not have a lip as shown in FIG. It was.

In the test, the first sample A with the lip and the second sample B without the lip are fixed to the fixing member 3 as shown in FIGS. 3A and 3B, respectively, and the pressing member 4 is When the contact member 4 is in contact with the outer surface of the hollow part of each sample without any deformation as a reference point 0, when the pressing member 4 goes to the + section, the relative distance f becomes the + value, and if it goes to the-section, the gap The relative distance f to be generated has a value of-. Unit: mm

And the buzzer (5) which is a sound source was moved from top to bottom, and the vertical distance s which becomes a noise distance was changed. The numerical values of the vertical distance s are 20 mm, 30 mm,... This is the number.

Table 1 and Table 2 show the results of measuring the dB values appearing on the external volume meter 7 (notation) and the internal volume meter 6 (notation) while the buzzer 5, which is a sound source, outputs sound. .

Table 1 is based on the first sample (A), Table 2 is due to the second sample (B).

As a result of the test, the difference between the numerically lip and the non-lip weather strip (first and second samples) is the value of each dB when the vertical distance s is 20 with the relative distance f of Tables 1 and 2 being 0. As can be seen clearly from the difference, the lip side has higher sound insulation efficiency.

As a result of testing various types of weather strips which are not presented as described above by the test method of the present invention, the conclusion obtained is that the longer the lip is advantageous in terms of sound insulation efficiency, and the hollow outer surface having a wider area of contact with the pressing member is obtained. It was found to be advantageous, and it was advantageous for the lip to roll into the hollow part.

Since the present invention can be tested statically, it is possible to completely eliminate the side effects (error occurrence) that can be raised in the existing weather strip sound insulation efficiency test method (dynamic test method), so as to secure accurate comparative evaluation data. In this case, the test time per sample can be shortened to less than one hour, which was conventionally required for more than two hours, and can reduce the fuel cost and the number of working people. It is possible to prevent safety accidents due to high-speed driving, and because it can be tested indoors, it is possible to test all weather.

Claims (2)

A relative distance between the weather strip and the pressing member is installed in a state in which a pressing member having a relative displacement in the left and right direction is treated in a sealed space and a sound source is vertically displaced on the weather strip outside the sealed space. And a sound insulation efficiency static test method of a vehicle door weather strip configured to adjust the vertical distance of the sound source and to measure the change of sound pressure inside and outside the sealed space. A weather strip, a fixing member for fixing the weather strip, a sealed measuring box on which the fixing member is mounted, and a stretch amount and a gap generation amount with the weather strip are slid left and right on the measuring box. Automobile door weather consisting of a pressing member that is movably installed, an internal volume meter installed inside the measuring box, an external volume meter installed outside the measuring box, and a buzzer installed vertically above the weather strip. Sound insulation efficiency static test execution device of strip.