RU2665500C1 - Method for determining glass transition temperature - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: invention relates to the field of measurements and can be used to study the thermophysical characteristics of electrical insulating materials. According to the proposed method for determining the glass transition temperature, a series of tests are carried out by indenter pressing into the surface of the test material at a smoothly varying temperature. Indentation is carried out by the ball indenter with registration during the test of the indentation diagram in the coordinates "load – depth of the impression", with the use of which the HB, Brinell hardness values for each of the test temperatures. Plot a graph for the Brinell hardness HB, from the test temperature. Approximate the resulting graph by two straight lines corresponding to the temperature intervals before and after vitrification. Glass transition temperature is determined from the point of intersection of the obtained straight lines on the graph of the hardness HB, on the temperature.EFFECT: increased productivity and accuracy of glass transition temperature.1 cl, 2 dwg

Description

The invention relates to the field of measurements and can be used to study the thermophysical characteristics of electrical insulating materials, in particular the glass transition temperature.

A known method for determining the glass transition temperature of polymeric and composite materials (Author's certificate SU No. 1295309, IPC G01N 25/04, publ. 07.03.1987), according to which a sample of the test material, previously loaded with a given compression force, is continuously heated, while measuring the dependence of the thermal elongation of the sample on temperature, and the glass transition temperature is taken to be the temperature of the sample at the moment it loses longitudinal stability, which corresponds to the moment of termination or reduction of its thermal extension eniya.

The disadvantages of this technical solution are the need for manufacturing samples, limited scope due to the possibility of testing materials only with a previously known modulus of elasticity, as well as the complexity due to the need to use a large amount of equipment and equipment for testing.

The closest in technical essence to the present invention is a method for determining the glass transition temperature of insulating materials by microindentation (Natsik V.D., Fomenko L.S., Lubenets S.V. Creep and glass transition analysis of elastomers by microindentation: epoxy resin and nanocomposites based on it // Solid State Physics, 2013, Volume 55, Issue 5, P. 940-952), according to which a thin metal film is sprayed on the surface of the test material, then a series of tests is carried out by microindentation four with the cross-linked Vickers pyramid at different temperatures, each print test measures the lengths of the diagonals of the prints, taking into account which the values of Vickers hardness are determined, and the glass transition temperature corresponding to a sharp change in hardness values is determined from the temperature dependence of the Vickers hardness.

The disadvantages of this technical solution are the high complexity associated with the need for preliminary spraying on the surface of the test material a thin metal film for visualizing prints, low productivity and subjectivity of the results associated with the need to measure the geometric parameters of the prints by the operator, as well as low measurement accuracy due to the influence of mechanical properties of metal coatings on determined hardness values.

The technical task of the invention is the ability to determine the hardness of the test material by the depth of the imprint using software.

The technical result consists in reducing the complexity, increasing productivity and accuracy of determining the glass transition temperature.

This is achieved by the fact that in the known method for determining the glass transition temperature, which includes a series of tests by indenting an indenter on the surface of the test material at a smoothly varying temperature, the indentation is carried out by a ball indenter during registration of the indentation diagram in the coordinates “load - imprint depth” using which calculate the Brinell hardness HB _t for each of the test temperatures, plot the Brinell hardness HB _t on temperature, and tests, approximate the obtained graph with two straight lines corresponding to the temperature ranges before and after glass transition, and the glass transition temperature is determined by the intersection of the obtained straight lines in the graph of the hardness HB _t versus temperature.

The essence of the invention is illustrated by drawings, where in FIG. 1 shows a diagram of the indentation of a ball indenter for an insulating material of the RIP type (insulating material obtained on the basis of crepe paper dried in vacuum and impregnated with epoxy resin) at a temperature of + 23 ° C, in FIG. Figure 2 shows the Brinell hardness HB _t as a function of the test temperature for an RIP type insulating material.

Implementation of the proposed method for determining the glass transition temperature is as follows.

The tests are performed on a stationary hardness tester that implements the instrumental indentation method and is equipped with a temperature chamber. For the test material, a series of indenter indentation tests is carried out at a smoothly varying temperature. The test temperature range and the step between the test temperatures are selected based on the physicomechanical properties of the material and the required accuracy of determining the glass transition temperature. At each of the given temperatures, an indenter in the form of a ball of radius R is pressed into the surface of the material with a continuously increasing load to a predetermined maximum value of P _max , and during the test, an indentation diagram is continuously recorded in the coordinates "load P - imprint depth t".

For each indentation, the Brinell hardness value HB _{t is} calculated using the formula

where t _to - the imprint depth under the load P _max .

According to the results of determining the hardness HB _t at various temperatures, the temperature dependence of the hardness HB _t is constructed.

It was experimentally established (Demidov A.N., Karimbekov M.A., Marchenkov A.Yu., Matyunin V.M. Operational assessment of the glass transition temperature of insulating materials for high-voltage bushings // Materials Science. 2016. No. 8. P. 11-15) that for epoxy resin-based insulating materials, the temperature dependence of hardness HB _t has two characteristic sections that can be approximated by straight lines with different slopes, and the intersection point of these lines corresponds to the glass transition temperature.

The reliability of this method for determining the glass transition temperature is confirmed by GOST 32618.2-2014, which governs the determination of the glass transition temperature T _s at the point of intersection of two straight lines approximating the temperature dependence of the thermal elongation of the sample in the temperature ranges before and after glass transition. The transition of the material to a highly elastic state when the glass transition temperature is reached is accompanied by a decrease in the plastic deformation resistance of the material, for example, an increase in elongation due to tensile stresses or a decrease in hardness when the indenter is pressed. Due to the similarity of the dependences of the thermal elongation of the sample and Brinell hardness HB _t on temperature, in the proposed method the glass transition temperature T _s is determined by analogy with GOST 32618.2-2014 at the point of intersection of two straight lines approximating the dependence of Brinell hardness HB _t on temperature in temperature intervals before and after glass transition.

Due to the use of the depth of the prints as a geometric parameter, measured using the software of the hardness tester during indentation, the proposed method eliminates the need for coating the test surface to visualize the prints and the need to visually measure the geometric parameters of the prints. Thus, the test performance and their accuracy are increased, because the distortion of the determined values of the characteristics of hardness by coatings applied to the surface of the material is excluded. The influence of the human factor on the results is also reduced. This allows you to increase the performance and objectivity of the method for determining the glass transition temperature, as well as to increase its accuracy.

The implementation of the proposed method is shown by the example of testing an insulating material of the RIP type. The tool indentation test at different temperatures was performed with a ball indenter of radius R = 1.25 mm with a maximum specified load P _max = 18 kgf (177 N) and a strain rate of 0.5 mm / min. The required test temperature was created in the climate chamber. The tests were carried out at temperatures + 23, + 40, + 50, + 60, + 70, + 80, + 90, + 100, + 110 and + 120 ° С. In FIG. 1, an indentation chart recorded at a test temperature of + 23 ° C. is shown as an example. In FIG. 1, the following designations are adopted: P - indentation load; t is the imprint depth; P _max - maximum indentation load; t _to - the imprint depth under load P _max .

Values Brinell hardness HB _t programmatically determined using indentation diagrams of data and formulas (1) and then plotted the Brinell hardness of HB _t test temperature shown in FIG. 2. In FIG. 2 the following designations are accepted: HB _t - Brinell hardness; T is the temperature; T _s is the glass transition temperature. From the point of intersection of the oblique straight lines approximating the experimental data, the glass transition temperature T _C = 98 ° C was determined on the graph of the Brinell hardness HB _t as a function of temperature.

The use of the invention allows to reduce the complexity, increase productivity and accuracy of determining the glass transition temperature.

Claims (1)

A method for determining the glass transition temperature, which consists in carrying out a series of tests by indenting the indenter on the surface of the test material at a smoothly varying temperature, characterized in that the indentation is carried out by a ball indenter with registration of the indentation diagram during the test in the coordinates “load - imprint depth”, using which the values are calculated Brinell hardness HB _t for each of the test temperatures, plot the Brinell hardness HB _t on the test temperature, and the obtained graph is approximated by two straight lines corresponding to the temperature ranges before and after glass transition, and the glass transition temperature is determined by the intersection point of the obtained straight lines in the temperature dependence of hardness HB _t .

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