KR101349077B1 - Testing method for measuring recovery of a rubber article from deformation - Google Patents

Abstract

The present invention relates to a method for measuring deformation recovery of a rubber material, and more particularly, a deformation recovery measurement of a rubber material that indirectly calculates an instant recovery rate using a recovery rate according to a measurement time after an aging test through a convenient O-ring deformation method. It is about a method.

To this end, the present invention is to prepare a test piece using a rubber material to a thickness of 1.0 ~ 5.0mm, the first step of preparing to form a width of the test piece larger than its thickness and less than half of the length; A second step of repeatedly performing a tensile test in which the test piece is uniformly stretched and released in the longitudinal direction; A third step of deforming the test piece into an o-ring shape and then maintaining a round shape for a predetermined time at a constant temperature; Leaving the test piece at room temperature for 30 minutes and then releasing the epicenter; After 30 minutes have elapsed from the rounded state, the distance between both ends of the test piece is measured four times or more, in 0.1 mm units, and the recovery rate is calculated. Using this recovery rate, an optimal linear equation (y = ax It provides a method for measuring the recovery of deformation of the rubber material, characterized in that it comprises a;

Rubber, tensile, compression, aging, deformation, permanent deformation, recovery, recovery rate, instant recovery rate

Description

Testing method for measuring recovery of a rubber article from deformation}

The present invention relates to a method for measuring deformation recovery of a rubber material, and more particularly, a deformation recovery measurement of a rubber material that indirectly calculates an instant recovery rate using a recovery rate according to a measurement time after an aging test through a convenient O-ring deformation method. It is about a method.

In general, rubber materials that require vibration and sealing characteristics are evaluated for the degree of recovery according to elapsed time after deforming by aging and calculating the instantaneous recovery rate based on this to evaluate the vibration and sealing characteristics.

Methods for measuring the deformation of rubber materials include the KSM ISO 815 method for measuring the permanent compression rate of vulcanized or thermoplastic rubber at room temperature, high temperature or low temperature, and the permanent compression rate measurement set forth in ISO 815. This measuring method measures the recovery rate according to the elapsed time after aging of a cylindrical disk provided with a type A test piece having a diameter of 29 mm and a thickness of 12.5 mm and a type B test piece having a diameter of 13 mm and a thickness of 6.3 mm using a compression device. Conduct. In addition, the rubber material should be careful in selecting specimens because the dimensional stability deteriorates when the specimens are thick in nature.

The instantaneous recovery rate is one of the required properties of the rubber material and indicates the response characteristic to external impact, and it is currently impossible to directly measure the instantaneous recovery rate of the rubber material, so it should be measured by an indirect method.

Existing compression test method for calculating the instantaneous recovery rate has a problem that it is difficult to calculate the instantaneous recovery rate using the recovery rate because the change in recovery rate with the aging (measurement) time of the rubber material shows a non-linear behavior.

In addition, the conventional compression test method is a method for measuring the permanent compression shrinkage after the high temperature acceleration test has a disadvantage that a large space is required due to the volume and weight of the compression device in the aging test.

The present invention has been invented to solve the above problems, using the O-ring deformation method to calculate the optimum linear equation according to the measurement (elapsed) time using the recovery rate according to the deformation caused by aging the rubber material It is an object of the present invention to provide a method for measuring strain recovery of a rubber material, which calculates an instantaneous recovery rate approximating the actual measured value by using this linear equation.

In order to achieve the above object, the present invention provides a test piece having a thickness of 1.0 to 5.0 mm using a rubber material, the first step of preparing to form a width of the test piece larger than its thickness and less than half of the length; A second step of repeatedly performing a tensile test in which the test piece is uniformly stretched and released in the longitudinal direction; A third step of deforming the test piece into an o-ring shape and then maintaining a round shape for a predetermined time at a constant temperature; Leaving the test piece at room temperature for 30 minutes and then releasing the epicenter; After 30 minutes have elapsed from the rounded state, the distance between both ends of the test piece is measured four times or more, in 0.1 mm units, and the recovery rate is calculated. Using this recovery rate, an optimal linear equation (y = ax It provides a method for measuring the recovery of deformation of the rubber material, characterized in that it comprises a;

Or, further comprising the step of immersing the test piece of the second step in the liquid medium at room temperature for 3 days, and in the third step the test piece deformed in the form of an o-ring in the liquid medium to maintain a rounded state ,

Preferably, when the recovery rate is no longer increased, the specimen is regarded as permanently deformed and is not applied when calculating an optimum linear equation.

In addition, the test piece is characterized in that the width 3.0 ~ 20.0mm, length 30.0 ~ 200.0mm,

More preferably, both ends of the test piece are fixed with pins or fixed using a circular jig to maintain the test piece in a rounded state.

The present invention relates to a method for measuring the recovery rate of deformation after the aging test of the rubber material, to measure the recovery rate of the dustproof rubber material and the sealing rubber material as well as other dustproof rubber or sealing materials used in automobiles to measure the dust and sealing properties Can be evaluated

In addition, since the change in the recovery rate according to the measurement time is excellent in linearity and satisfies the linear function, the instantaneous recovery rate, which is the instantaneous response force to the external impact, can be calculated using the linear function.

In addition, the test piece used in accordance with the present invention is relatively small in size compared to the conventionally used test piece is suitable for mass aging test, and excellent in the reproducibility of the test result is efficient.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present disclosure, and the singular forms “a”, “an” and “the” include plural forms unless the context clearly indicates otherwise.

In the description of the present invention, overlapping descriptions of the same parts as in the prior art may be omitted.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Deformation recovery measurement method of the rubber material according to the present invention measures the recovery rate for various deformation of the rubber material through the O-ring deformation method, by measuring the instantaneous recovery rate by using the optimum linear equation calculated by using the dust-proof and Evaluate the sealing properties.

In order to use in the aging test according to the present invention, a test piece is prepared by using a compression mold having a thickness of 1.0 to 5.0 mm, and then prepared to a desired width and length. If it is correctly cut, use the finished specimen as it is, and if the specimen is provided with a thickness thicker than 1.0 ~ 5.0 mm, grind it and use it with the correct dimensions. Dimensional stability depends on the thickness of the specimen, so prepare the specimen with the correct dimensions.

The width of the specimen shall be wider than the thickness of the specimen and shall not exceed 50% of the specimen length. If the width of the specimen is less than the thickness of the specimen or exceeds 50% of the specimen length, it will not be easy to maintain the circle.

And the length of a test piece is arbitrarily adjusted according to the magnitude | size of compression and tension. In other words, if the specimen has a relatively high degree of compression and tension, the length of the specimen should be shortened. If the specimen has a relatively low degree of compression and tension, the specimen should be prepared with a relatively long length.

Here, although it is possible to manufacture a relatively thick thickness of the test piece in order to increase the degree of compression and tension of the test piece, it is preferable to adjust the length of the test piece because the dimensional stability varies depending on the thickness of the test piece as described above.

The present invention uses a test piece having a thickness of 1.0 to 5.0 mm, a width of 3.0 to 20.0 mm, and a length of 30.0 to 200.0 mm, preferably a thickness of 2.0 to 3.0 mm, a width of 4.0 to 12.0 mm, and a length of 120.0 mm, which is the easiest to manufacture. I use it.

Record the thickness, width, and length of the prepared specimens and perform the aging test in the atmosphere (air) or in a liquid medium such as water or oil. Moreover, it can also be performed in the presence state of an ozone chamber or a specific gas according to a test objective.

1 and 2 are a flow chart showing some processes of the method for measuring the deformation recovery of the rubber material according to the present invention.

First, when the aging test is carried out in the atmosphere, the test piece prepared as described above was stretched to 100% in the longitudinal direction, and then repeated 3 to 10 times, and the thickness, width, and length of the test piece were recorded, and in FIGS. 1 and 2. As shown in the figure, deform to form a perfect circle in the form of an O-ring to fix both ends of the test piece with pins (P) or to maintain the roundness using a circular jig (R) and to maintain a constant temperature. Place in a convection oven or indoors or outdoors for a period of time.

The aging temperature and duration are arbitrarily set according to the test purpose, but in the case of high temperature accelerated aging, the aging temperature is preferably 50 ° C. or more and 110 ° C. or less.

Maintaining a round shape as described above, and left for 30 minutes at room temperature after aging in a state of tension / compression (when the test piece is transformed into a round shape, the inside of the test piece is compressed and the outside is stretched). Next, remove the pin (P) at both ends or remove the specimen from the circular jig (R).

Next, when the aging test is carried out in a liquid medium, the prepared test piece is stretched to 100% and loosened for 3 to 10 times to record the thickness, width, and length of the test piece.

After repeating the tensile test, the specimen was immersed in the liquid medium for 3 days at room temperature, and then its thickness, width, and length were measured.

Accordingly, the swollen test piece is deformed to have a perfect round shape in the form of an o-ring as shown in FIGS. 1 and 2, and then both ends of the test piece are fixed with pins (P) or a circular jig (R). Soak it in a liquid medium and leave it in a convection oven or at room or outdoor for a period of time.

After the specimen is aged for a certain period of time as described above, it is taken out of the liquid medium and left at room temperature for about 30 minutes, and then the pins (P) at both ends of the specimen are removed or the specimen is removed from the o-ring (circular) jig (R).

In order to measure the recovery rate of the aged test piece as described above, the distance between both ends of the test piece is measured to the unit of 0.1 mm, and all measured values less than 0.1 mm are discarded.

At this time, in order to estimate the linear function (y = ax + b) from the recovery rate calculated by using the distance measurement value at both ends of the test piece (hereinafter referred to as the measurement value at both ends), the distance measurement at both ends of the test piece is performed by pins at both ends. Remove or remove the specimen from the circular jig and perform at least four times between approximately 100 minutes and 100 days.

Recovery rate is calculated by the following equation.

Recovery rate, R (%) = 100 * (r2) / (r1)

Here, r1 and r2 refer to both end distances (initial test piece length) of the test pieces before the aging test and both end distances of the test pieces after the aging test, respectively.

Here, the time elapsed after removing the pin from both ends of the test piece or removing the test piece from the circular jig, that is, the measurement time, t, the x-axis is logt and the y-axis is plotted as the recovery rate (R). calculate b).

At this time, if the measured recovery rate does not increase any more, the permanent deformation of the test piece occurs, so this measurement value is not applied to the calculation of the linear equation.

The instantaneous recovery rate of the test piece can be calculated by substituting the instantaneous time value t of 1.0 second or less into the optimal linear equation thus calculated.

Hereinafter, an embodiment according to the present invention will be described.

3 is a graph showing a change in recovery rate with a measurement time of Example 1 according to the present invention, Figure 4 is a graph showing a change in recovery rate with a measurement time of Example 2 according to the present invention.

Example 1

A test piece having a thickness of 2.0 mm, a width of 8.0 mm, and a length of 120.0 mm was prepared, and the test piece was stretched up to 100% and then loosened five times to record the thickness, width, and length of the test piece. The form is deformed to a full circle and then left for 7 days in a convection oven maintained at 80 ° C. with a pin.

Next, remove the test specimens from the convection oven and leave them at room temperature again for 30 minutes, and then remove the pins. After each 30 minutes, 1 hour, 4 hours, 8 hours, 12 hours, 24 hours, 96 hours, 168 hours, Measure the distance between the ends of the specimen at each time point of 240, 360, 480 and 720 hours.

When the measured value is substituted into the formula of R (%) = 100 * (r2) / (r1) and the recovery rate is represented by the y-axis and the x-axis is logt, the graph shown in FIG. 3 is obtained. Calculating the linear equation, y = 4.141 logt + 82.26, where the correlation coefficient is 0.994.

9 * 10 ^-1 seconds (1 * 10 ^-5 days), 9 * 10 ^-2 seconds (1 * 10 ^-6 days), 9 * 10 ^-3 seconds (1 * 10 ^-7 days) using this straight line The instantaneous recovery rate is measured at 61.6%, 57.4%, and 53.3%, respectively, and these measurements are very close to the actual measured instantaneous recovery rate because the correlation coefficient is very close to 1. The equation can be used to find the instantaneous recovery rate.

Example 2

A test piece having a thickness of 2.0 mm, a width of 8.0 mm, and a length of 120.0 mm was prepared, and the test piece was stretched to 100%, and the test piece was repeated six times. The thickness, width, and length of the test piece were recorded, and the test piece was placed in distilled water at room temperature. After soaking daily, measure the thickness, width and length.

The swollen test piece is deformed to a perfect round shape in the form of an O-ring, and then fixed to both ends of the test piece by pins, soaked in distilled water while maintaining a round shape, and left for 7 days in a convection oven maintained at 80 ° C.

Next, remove the test specimen from the convection oven and leave it at room temperature again for 30 minutes, then remove the pins on both ends of the test specimen, and after 1 hour, 4 hours, 8 hours, 12 hours, 24 hours, 96 hours, Measure the distance between the ends of the specimen at each of 168, 240, 360, 480 and 720 hours. At this time, the distance of both ends of a test piece is measured to 0.1 mm unit, and all the measured values less than 0.1 mm are discarded.

When the measured value is substituted into the formula of R (%) = 100 * (r2) / (r1) and the recovery rate is set to the y-axis and the x-axis is logt, the graph as shown in FIG. 4 is obtained. The equation yields y = 6.731 logt + 82.86, with the correlation coefficient r being 0.996.

9 * 10 ^-1 seconds (1 * 10 ^-5 days), 9 * 10 ^-2 seconds (1 * 10 ^-6 days), 9 * 10 ^-3 seconds (1 * 10 ^-7 days) using this straight line The instantaneous recovery rate is calculated from 49.2%, 42.5%, and 35.8%, respectively, and these measurements are very close to the actual measured instantaneous recovery rate because the correlation coefficient is very close to 1. The equation can be used to calculate the instantaneous recovery rate indirectly.

As can be seen in Examples 1 and 2 above, the optimum linear equation calculated according to the present invention shows a very good linearity with a correlation coefficient of 0.99 or more, so it can be confirmed that it is reasonable to obtain an instantaneous recovery rate using the linear equation.

While the invention has been shown and described with respect to certain preferred embodiments thereof, the invention is not limited to these embodiments, and has been claimed by those of ordinary skill in the art to which the invention pertains. It includes all the various embodiments that can be carried out without departing from the spirit.

1 and 2 is a flow chart showing a part of the process of measuring the deformation recovery of the rubber material according to the present invention,

3 is a graph showing a change in recovery rate according to measurement time of Example 1 according to the present invention;

Figure 4 is a graph showing the change in recovery rate with a measurement time of Example 2 according to the present invention.

Claims (5)

A first step of preparing a test piece using a rubber material to a thickness of 1.0 ~ 5.0mm, forming the width of the test piece larger than the thickness and less than half of the length; A second step of repeatedly performing a tensile test in which the test piece is uniformly stretched and released in the longitudinal direction; A third step of deforming the test piece into an o-ring shape and then maintaining a round shape for a predetermined time at a constant temperature; Leaving the test piece at room temperature for 30 minutes and then releasing the epicenter; After 30 minutes have elapsed from the rounded state, the distance between both ends of the test piece is measured four times or more, in 0.1 mm units, and the recovery rate is calculated. Using this recovery rate, an optimal linear equation (y = ax calculating + b); Deformation recovery measurement method of a rubber material, characterized in that comprises a. Recovery rate (%) = 100 * [both ends of test piece after aging test (r2) / both ends of test piece before aging test (initial test piece length) (r1)] (The time to measure the distance between both ends of the specimen at y = ax + b is x = logt, y is the recovery rate, and a and b are constants.) The method according to claim 1, And immersing the test piece of the second step in a liquid medium at room temperature for three days, and immersing the test piece deformed in the form of an o-ring in the third step in a liquid medium in a rounded state. How to measure the strain recovery of a material. The method according to claim 1, When the recovery rate is no longer increased, deformed recovery measurement method of the rubber material, characterized in that the test piece is considered to be permanently deformed and is not applied when calculating the optimum linear equation. The method according to claim 1, Said test piece is 3.0-20.0 mm in width, 30.0-200.0 mm in length, The recovery method of the deformation | transformation of the rubber material characterized by the above-mentioned. The method according to claim 1 or 2, In the third step, in order to maintain the test specimen in a circular state, both ends of the test piece fixed by pins or by using a circular jig, characterized in that the deformation recovery measurement method of the rubber material.

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