SU1437755A1 - Method of determining the thermal effects of broad-temperature irrevesible processes in materials - Google Patents

Abstract

The invention relates to thermophysics and can be used to determine the magnitudes of the thermal effects of wide-temperature irreversible physicochemical transformations in materials subjected to heating, in particular the processes of thermal destruction of composite polymeric materials used for thermal protection of high-temperature objects. The purpose of the invention is to simplify the determination process. The sample of material is heated in a cell of a differential scanning calorimeter cyclically from the initial temperature below the start of the conversion to several successively increasing temperatures in the conversion interval. When each of the selected temperatures is reached, the sample is cooled to the initial temperature at a rate of at least 5 K / s. Then, the conversion product is heated over the entire temperature range of the conversion. The magnitude of the thermal effect is calculated from the curves of the differential thermal power. The baseline of the peak of the thermal effect is graphically restored and its value is calculated from the area of this peak .; from sl with i4 Od Ch cl SP

Description

The invention relates to thermophysics and can be used to determine the thermal effects of pelicin wide-temperature irreversible physicochemical transformations in materials subjected to heating, in particular the processes of thermal destruction of composite polymeric materials used for thermal protection of high-temperature objects.

The purpose of the invention is to simplify the process of determining

The proposed method is carried out as follows.

To determine the temperature range for the transformation of the material under investigation, continuous heating is carried out with a constant speed of the crucible with a sample n of one of the cells of the differential scanning calorimeter in the temperature range covering the process of transformation

On the recorded differential power curve, including the transformation peak, set the transformation start temperature (at the point of deviation of the curve from the previously established direction), process termination temperature (at the exit point of the curve in the steady direction after the peak) and select several intermediate temperatures from in such a way that the curve between these temperatures consistently covers the beginning of the process the ascending branch of the peak, the peak of the peak, the descending branch and the end of the process. ,

After placing the crucible with the new sample in the same cell (the second cell remains empty), it is heated at the same speed from the initial temperature below the transformation start temperature to the First of the selected temperatures and when it is reached, the sample is quickly frozen to the initial temperature at a rate not less than 5 K / s. Similar cyclic heating of the sample to the remaining selected temperatures, including the conversion end temperature, is then carried out successively.

Lastly, the conversion product is heated in the entire temperature range that covers the transformation process.

The resulting differential power curves are rearranged relative to the curve for the conversion product, which is taken as zero.

Q line. The two extreme points of the future baseline of the transformation peak are known: the first is on the first of the recorded differential curves at the previously set temperature at the beginning of the conversion process, the last is on the differential power curve for the product at the previously set temperature at the end of the process. Extrapoliruate initial

0, the section of each subsequent curve on the ordinate of the extreme point of the previous curve is obtained when they cross the rest of the points belonging to the baseline of the peak. Connecting all

5 indicated points, get the baseline of the peak, and by constructing the envelope of all recorded sections of the differential power curves, limit the peak completely. Area received

0 peak corresponds to the true thermal effect of transformation

Claims (1)

Invention Formula 5 A method for determining the thermal effects of wide-temperature irreversible processes in materials, consisting in heating first the sample of material in a cell of a differential 0 of a scanning calorimeter at a constant rate in the temperature range of the material, then the product of conversion, and calculating the desired value according to the curves of the differential thermal power, characterized in that, to simplify the determination process, the sample is heated cyclically from the initial temperature below the beginning converting to several successively increasing temperatures in the range of transformation and upon reaching each of the indicated temperatures, the sample is cooled to the initial temperature at a rate of w of at least 5 K / s.0