KR20030000247A - Tester of compression elasticity ratio - Google Patents

Abstract

PURPOSE: A compression elasticity ratio measurement device is provided to achieve improved convenience for testing and reliability for test result by measuring thickness of test piece immediately after the outworn of the test piece. CONSTITUTION: A compression elasticity ratio measurement device comprises a base(10); a first panel(20) installed on the base and supported by an insulator(21); a second panel(30) disposed on a test piece(100a) which is mounted on the first panel; a support(40) and a scale ruler(41) arranged to the base in such a manner that the support and the scale ruler are disposed at the side of the first panel; and a weight support(50) installed at the top of the support. The first panel has an upper surface set to zero scale mark of the scale ruler.

Description

Tester of compression elasticity ratio

The present invention relates to a compressive modulus measuring device, and more particularly, to a compressive modulus measuring device that can significantly reduce the measurement error by allowing the thickness to be measured immediately after aging of the soundproofing material in the compressive modulus evaluation test.

In general, a vehicle is equipped with various facilities for increasing the driver's convenience.

Figure 1 shows the installation location of the soundproof material 100 to absorb the noise inside the vehicle and to prevent the noise from entering the room from the outside of the vehicle among these various facilities.

In the case of a passenger car, the soundproof material 100 is installed in a place that can be introduced into a vehicle interior, that is, a dash panel, a floor, a roof, a trunk, or the like. The soundproofing material 10 is usually made of fibrous felts such as resin pelts, PET fibers, PE felts, and the like.

The soundproof material 100 evaluates specific physical properties, for example, strength, heat resistance, cold resistance, oil resistance, chemical resistance, sound absorbing and insulating property, adhesiveness, compressive modulus, and the like, suitable for various application positions described above.

In particular, since the sound absorbing material absorbs the noise generated inside and outside the vehicle and converts it into thermal energy to reduce the noise, a certain space is required inside the material and whether the space is maintained even if the material is aged. Compression modulus evaluation is made to determine.

The compression modulus evaluation is made in the following order. First, a test piece is arbitrarily taken and placed between two steel sheets, the thickness of the test piece is measured, and weights (about 500 g or so) are placed thereon, and aged under heat and humidity conditions. Subsequently, after removing the weight, the thickness of the test piece was measured after standing for 1 hour at standard conditions, and the compressive modulus was evaluated according to the following equation (1).

Compressive modulus (%) = (thickness of test piece before aging) / (thickness of test piece after aging) * 100

However, in the conventional compressive modulus measurement method, since the thickness before and after aging, which is an important factor in determining the compressive elastic modulus, is measured by using a vernier caliper, a problem arises in that the exact thickness cannot be measured.

That is, since the test piece itself has elasticity, its thickness may vary according to the force of the operator operating the vernier caliper, and the thickness of the test piece may not be measured precisely as the test piece is stretched by the test piece's own elastic force. It remains a big problem in evaluating the modulus of elasticity and needs improvement.

The present invention has been devised in view of the above, and by measuring the thickness of the test piece immediately before aging in a state where the test piece is mounted on the test apparatus, the thickness after aging can be measured directly from the test piece aged under the aging conditions. An object of the present invention is to provide a compression casing rate measuring device that can obtain a precise and reliable compression modulus.

1 is a perspective view showing various soundproofing materials installed in a vehicle,

2 is a block diagram showing the configuration of a compression modulus measuring device according to the present invention.

[Description of Symbols for Main Parts of Drawing]

10: base 20: first panel

21: insulator 30: second panel

31: moving ruler 40: support

41: ruler 50: weight support

60: weight 100: soundproof material

100a: test piece

The present invention for realizing this, the base panel, the first panel provided with the support of the insulator on the base, the second panel placed on top of the test piece mounted on the upper part of the first panel, and the side of the first panel Characterized in that consists of a support and a ruler installed on the base to be located in, and a weight support provided on the upper portion of the support.

In a preferred embodiment of the invention, the first panel is characterized in that the top surface is aligned with "0" of the ruler.

In addition, the second panel is characterized in that the lower surface is aligned with the scale "0" of the moving ruler moving along the ruler.

In addition, the moving ruler is characterized in that the graduation interval of the ruler is different.

Hereinafter, with reference to the accompanying drawings, the configuration and effect of the present invention will be described.

2 is a block diagram showing the configuration of a compression modulus measuring device according to the present invention. Here, reference numeral 100 denotes a soundproof material, and 100a denotes a test piece collected from the soundproof material.

The present invention is for easily measuring the compressive elastic modulus of the test piece 100a taken from the sound insulation material 100, and includes a base 10 having a predetermined size. The base 10 is configured to maintain a horizontal state with respect to the ground and supports other components to be described later.

In addition, the first panel 20 is horizontally mounted on the upper portion of the base 10 via the insulation 21, and the test piece 100a is placed on the first panel 20. Here, the insulator 21 is mounted on the lower part of the first panel 20 for the purpose of reducing the influence of the temperature transmitted from the base 10 to the first panel 20 in the temperature condition during aging.

In the preferred embodiment of the present invention, the first panel 20 is mounted horizontally on the base 10, but is mounted so as to be positioned horizontally with the scale "0" of the ruler 41 to be described later It is preferable to make it the reference | standard which measures the thickness of the test piece 100a.

The second panel 30 is provided on the first panel 20. The second panel 30 is placed on the upper portion of the test piece 100a placed on the upper portion of the first panel 20 to be used. At this time, the second panel 30 evenly distributes the load of the weight 51 placed thereon on the test piece 100a.

In addition, the second panel 30 is provided with a moving ruler 31 at one end thereof. The moving ruler 31 is fitted to the above-described ruler 41 so as to slide up and down to show the height of the second panel 30, that is, the thickness of the test piece 100a.

In a preferred embodiment of the present invention, the second panel 30 is installed so that the lower surface is aligned with the scale "0" of the moving ruler 31, so that the test piece 100a as the second panel 30 moves up and down. It is desirable to be able to accurately measure the thickness of.

In addition, the scale of the moving ruler 31 is preferably made to have a different interval from the scale of the ruler 41, so that it is possible to read a more accurate scale, such as how to read the scale in the vernier caliper.

On the other hand, the support 10 is protruded to the base 10 perpendicular to the upper surface. In particular, the support 40 is attached to the ruler 41 having a constant scale on one surface.

In the preferred embodiment of the present invention, the ruler 41, as described above, so that the scale "0" coincides with the top surface of the first panel 20, the size of each scale is the scale of the moving ruler 31 It is preferable to set the size to be different from and to measure the thickness of the test piece 100a, as well as to read a more accurate reading.

In addition, the upper end of the support 40 is provided with a weight support (50). The weight support 50 supports the weight 51 necessary for measuring the compressive elastic modulus. In particular, the weight 51 is placed at the center position of the second panel 30 so that the weight of the weight 51 is increased. Preferably, the second panel 30 can be evenly applied to the entire second panel 30.

Compression modulus measuring device made in this way is to place the test piece (100a) on the first panel 20 and the second panel 30 on it. At this time, the second panel 30 is lowered together with the moving ruler 31 by its own weight, and since the first panel 20 is aligned with " 0 " of the ruler 41, the moving ruler 31 Reading the scale of the can be obtained the thickness of the test piece (100a) before aging.

In addition, the measuring device is to proceed the aging under the same conditions as the conventional method and then remove the weight 51, the test piece (100a) is pushed up the second panel 30 by its own elastic force, so If you read the scale when you lose it will be easy to know the thickness of the specimen (100a) after aging.

As described above, the present invention obtains the following effects by allowing the thickness of the test piece to be measured before and after aging based on two panels installed on both sides of the test piece.

1) Convenience is increased because the thickness can be obtained immediately after the test without using a separate thickness measuring tool to measure the thickness of the test piece.

2) Since the thickness of the test piece before and after aging can be obtained immediately after the test, the error of the thickness can be reduced, thereby increasing the reliability of the compressive modulus.

Claims (4)

Bass, A first panel provided on the base with support of an insulator; A second panel placed on an upper portion of a test piece mounted on an upper portion of the first panel, Support and ruler mounted on the base to be located on the side of the first panel, Compression modulus measuring device, characterized in that consisting of a weight support bar provided on the upper portion of the support. The compressive modulus measuring device according to claim 1, wherein the first panel has a top surface aligned with "0" of the ruler. The compressive modulus measuring device according to claim 1, wherein the second panel is aligned with a scale "0" of a moving ruler that moves along a ruler. 4. The compressive modulus measuring device according to claim 3, wherein the moving ruler has a different interval between graduations of the rulers.