KR20130085660A - Creep and stress relaxation tester for polymer materials - Google Patents

Abstract

PURPOSE: A polymer material creep and a stress relaxation tester are provided to accurately understand the mechanical property of the polymer material by testing the creep and the stress relaxation under the same environment, thereby enhancing the reliability of the endurance life prediction. CONSTITUTION: A polymer material creep and a stress relaxation tester comprise a heating furnace (20), a creep tester (30), and a stress relaxation tester (40). The heating furnace is located at the top. A plurality of test piece for the creep test and a test piece for the stress relaxation are located inside an identical space. The creep tester fixes the plurality of test piece for the creep test. The creep tester performs the creep test of the test pieces. The stress relaxation tester fixes the test piece for the stress relaxation test. The stress relaxation tester performs the stress relaxation test to the test piece.

Description

Creep and Stress Relaxation Tester for Polymer Materials

The present invention relates to a creep and stress relaxation tester, and more particularly, to a creep and stress relaxation tester of a polymer material capable of simultaneously performing a creep test and a stress relaxation test of a polymer material.

As is well known, creep refers to a phenomenon in which additional strain occurs over time when a constant load or stress is maintained at a specific temperature for a long time, and is especially designed for operation at high temperatures such as gas turbines and rocket engines. The time creep phenomenon must be taken into account. On the other hand, when a viscoelastic object is deformed and kept constant, the stress decreases with time. This phenomenon is called stress relaxation, and especially for viscoelastic materials such as rubber, The matter should be reviewed.

Recently, the use of polymer materials in various industries has increased. Therefore, researches to grasp the characteristics of the polymer material have been actively conducted. Among them, research on improving the durability of rubber parts has attracted much attention. The key to designing polymer parts is improving durability. In addition, in order to reduce the weight and improve the assembly performance, since the components of the conventional individual components have been actively developed and applied, improving the durability performance of the polymer component is recognized as a problem that must be preceded. Therefore, the endurance life of polymer parts should be predicted in the initial design stage. Accordingly, the creep test and the stress relaxation test to grasp the mechanical properties of the polymer material have a very important meaning.

As an example of a conventional creep test apparatus, Japanese Patent Laid-Open No. 2001-102724 (referred to as "quotation document 1") discloses a creep test apparatus for performing six test pieces. The device installs six specimens at an isometric angle of 60 degrees and uses six load cells 14 and six lever arms 12 to load the specimens to correspond to the specimens.

On the other hand, an apparatus for measuring the compressive stress relaxation characteristics of a high molecular compound which is an elastomer called an elastomer is disclosed in Japanese Patent Application Laid-Open No. 2009-111381 (called 'quotation document 2'). This measuring device applies compressive stress to the specimen (M) and evaluates the long-term performance of elastomeric materials used in harsh environments at high temperatures and pressures.

Moreover, the polymer material used in the present invention, particularly rubber, has properties such as large deformation, incompressibility, superelasticity, and viscoelasticity. In addition, since the standardized material does not exist, the material test is performed more frequently and variously than the steel material, and in the case of the polymer material, the stress relaxation test together with the creep test has an important meaning in order to evaluate its properties.

However, the reference 1 is low in accuracy of the result value, including the error accumulated by the indirect load transfer method using the pulley ratio, and therefore is not suitable for the measurement of the rubber material, especially large deformation occurs even at small loads There is a problem. Reference 2 is a technique for stress relaxation test of the compressive stress of the polymer compound, the creep test can not perform the tensile stress relaxation test necessary for the evaluation of the properties of the polymer material, and also the creep test can not be performed at all There are disadvantages.

In order to evaluate the properties of permanent deformation, durability, and the like of polymer materials, especially rubber materials, it is very necessary to develop a tester capable of accurately performing creep test and stress relaxation test under the same conditions.

On the other hand, conventionally, the grip method using the actuator system is adopted to fix the test piece, but after the grip is completed, the grip part is pushed out without being fixed due to the characteristics of the rubber. The problem is pointed out.

As described above, the present invention has been made to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide a creep and stress relaxation tester of a polymer material capable of simultaneously performing a creep test and a stress relaxation test. Another object of the present invention is to provide a creep and stress relaxation tester of a polymer material capable of accurately performing the characteristics of the test piece by minimizing the rolling error of the test pieces.

Creep and stress relaxation tester of the polymer material according to the present invention for achieving the above objects is a heating furnace in which a plurality of test pieces for the creep test and a stress relaxation test piece made of a polymer material is located inside the same space And, a creep test device for fixing a plurality of test pieces for creep test and performing creep tests on the test pieces, and a stress relaxation test device for fixing the test piece for stress relaxation test and performing a stress relaxation test on the test piece. .

Creep and stress relaxation tester of the polymer material according to the present invention has a remarkable effect that can test the durability of the polymer material at low cost and high efficiency by performing the creep test and the stress relaxation test at the same time.

In addition, the creep test and the stress relaxation test are performed under the same environment, thereby accurately understanding the mechanical properties of the polymer material, thereby increasing the reliability of the durability life prediction.

1 is a front view of a creep and stress relaxation tester of the polymer material according to the present invention,
2 is a side view of a creep and stress relaxation tester of the polymer material according to the present invention;
3 is a front view of the creep test apparatus of the creep and stress relaxation tester of the polymer material according to the present invention,
4 is a side view of a stress relaxation test apparatus of the creep and stress relaxation tester of the polymer material according to the present invention;
5 is an enlarged perspective view of part A of FIG. 3;
6A and 6B are graphs showing normalized creep compliance and stress relaxation modulus measured by a creep and stress relaxation tester according to the present invention, respectively.

Other objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments in conjunction with the accompanying drawings.

Hereinafter, with reference to the accompanying drawings, an embodiment of the creep and stress relaxation tester of the polymer material according to the present invention will be described in detail. In this embodiment, rubber is used as the polymer material.

1 and 2, the creep and stress relaxation tester of the polymer material of the present embodiment is a creep test device 30 and one stress relaxation test device having four of the same configuration as the heating furnace 20 as a main part It consists of 40.

The furnace 20 is arranged at the upper center of the frame 10 of the testing machine. Test pieces (Mc, Ms) are located in the heating furnace 20, the heating furnace 20 is designed to be maintained up to an ambient temperature of 200 degrees, this embodiment was tested at 70 degrees.

As shown in FIG. 3, the creep test apparatus 30 is equipped with the upper gripper 31 and the lower gripper 32 which fix the test piece Mc. Referring to FIG. 5, the upper end of the test piece Mc is inserted into the upper gripper 31, and the lower end of the test piece Mc is inserted into the lower gripper 32. The test piece Mc inserted into the upper gripper 31 and the lower gripper 32 is tightened by fastening the bolts 31a and 32a to the upper gripper 31 and the lower gripper 32. Therefore, the rubber test piece Mc is firmly fixed without being pushed. The upper gripper 31 is connected to the upper rod 33, and the upper fastener 35 of the upper end is fixed to the upper frame 10.

The lower gripper 32 is connected to the lower rod 34, and the pedestal 36 is positioned in the middle of the lower rod 34. A load weight 37 is placed on the pedestal 36, and a load of the load weight 37 acts on the test piece Mc by pulling the lower clipper 32 downward through the lower rod 34. Done. A displacement measuring sensor 38 is provided at the lowermost end of the creep test apparatus 30, and the displacement measuring sensor 38 is fixed to the lower part of the frame 10. The displacement measuring sensor 38 uses a rod-type Long Travel Extensometer and can detect displacement changes of at least 0.01 mm.

In this embodiment, as shown in Fig. 1, four creep test apparatuses 30 having the above-described configuration are provided. In general, Universal Testing Machines (UTMs) are difficult to measure for long periods of time and can only measure one specimen. On the other hand, because rubber materials are sensitive, testing of a single specimen alone does not guarantee reliability. Therefore, in this example, a plurality of preferably four test pieces are tested simultaneously.

Next, referring to FIG. 4, the stress relaxation tester 40 is installed on the right side of the creep test device 30, as shown in FIG. 1. The stress relaxation test piece Ms is located in the heating furnace 20 similarly to the creep test piece Mc.

The stress relaxation test apparatus 40 is provided with the upper gripper 41 and the lower gripper 42 which fix the test piece Ms. The upper end of the test piece Ms is fitted into the upper gripper 41, and the lower end of the test piece Ms is fitted into the lower gripper 42. The test piece Ms sandwiched between the upper gripper 41 and the lower gripper 42 is tightened by fastening the bolts 41a and 42a to the upper gripper 31 and the lower gripper 32. Therefore, the rubber test piece Ms is firmly fixed without being pushed. The upper gripper 41 is connected to the upper rod 43, and the upper fastener 35 of the upper end is fixed to the upper frame 10. Although not shown, the upper fixture 35 is provided with a detachable load cell for detecting the stress change of the test piece (Ms).

The lower gripper 42 is connected to the lower rod 44, and the lower rod 44 is operatively connected to the displacement control handle 46 to receive the tensile load. In the present embodiment, the tensile load is applied to the test piece Ms by the displacement control handle 46, but the configuration of the tensile load by the displacement control handle 46 may be replaced with another tensile load application configuration.

The inside of the heating furnace 20 is in communication, and the creep test piece Mc and the stress relaxation test piece Ms have the same atmospheric conditions, and the initial conditions are the same. Therefore, the creep test and the stress relaxation test are performed under the same conditions, so that the results of the creep test and the results of the stress relaxation test can be compared to obtain the result data of the test piece quickly and accurately in real time and to clearly evaluate the properties of the material.

6A and 6B are graphs of normalized creep compliance (NCC) and stress relaxation modulus (SRM) obtained by creep test and stress relaxation test under the same conditions. The normalized creep compliance of FIG. 6A represents stress / strain, indicating a measure of how much strain is at a fixed stress. The stress relaxation compliance of FIG. 6B represents strain / stress, and as with normalized creep compliance, the measure of strain can be seen. The numbers in both graphs are theoretically invertible. The graphs of FIGS. 6A and 6B are divided into initial compliance values and modulus values, respectively, and the initial value is set to 1, and is a dimensionless value. The reliability of the test can be assessed on its own by comparing the normalized creep compliance through creep test with the stress relaxation modulus through stress relaxation test. From the two graphs, it can be seen that the two values of creep compliance and stress relaxation modulus exhibit approximately opposite symmetrical values. This makes it possible to accurately and reliably evaluate and predict the viscoelastic behavior of the rubber material.

The embodiments described above are merely illustrative of the preferred embodiments of the present invention, the scope of the present invention is not limited to the described embodiments, those skilled in the art within the spirit and claims of the present invention It will be understood that various changes, modifications, or substitutions may be made thereto, and such embodiments are to be understood as being within the scope of the present invention.

10 frame 20 heating furnace
30: creep test device 40: stress relaxation test device

Claims (3)

A heating furnace positioned in an upper portion of which a plurality of test pieces for creep test and a test for stress relaxation test made of a polymer material are located in the same space;
A creep test apparatus which fixes the plurality of test pieces for the creep test and performs a creep test on the test pieces;
A creep and stress relaxation tester of a polymer material comprising a stress relaxation test apparatus for fixing the test piece for stress relaxation test and performing a stress relaxation test on the test piece. The method of claim 1, wherein the creep test apparatus includes a pair of upper grippers and lower grippers for fixing a test piece, and a load weight connected to the lower grippers by a lower rod to directly load the lower grippers. Creep and Stress Relaxation Tester. 3. The creep and stress relaxation tester of claim 2, wherein the test pieces are fitted to the upper gripper and the lower gripper and fixed by bolts.

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