SU591875A1 - Computer for differential thermal analysis - Google Patents

Description

(64) COMPUTATIONAL DEVICE FOR LIFE DIFFERENTIAL THERMAL ANALYSIS

direct current, and the output - with the input of the integrating unit.

The outputs of the multiplier-division and integrating units are the outputs of the device.

The drawing is given a functional diagram of the proposed device. The device contains a differential temperature-sensitive element 1, a DC amplifier 2, an additional DC amplifier 3, a voltage setpoint 4, a differentiating unit 5, a multiplier-dividing unit 6, a functional converter 7 and an integrating unit 8.

The atmosphere of the furnace space is used as the thermo-inert substance in the crucible for the standard in the thermoanalytical installation, and the crucibles of the standard and the sample are symmetrical in the thermophysical relation to the external heat flux) of the installation heater.

The device works as follows.

Before starting, the characteristics of the functional converter are adjusted separately for the approximate dependence of the heat transfer coefficient on the piecewise linear law of the current temperature (seven piece broken) in the study temperature range, as well as using the setpoint voltage input Z -., Multiply The separation unit is set to a voltage proportional to the mass of the sample. The amplified signal from the midpoint of the differential temperature-sensitive element, proportional to the current heating temperature, enters the inputs of the differentiating unit and functional converter, the output of which, respectively, generates signals proportional to the heating rate and sample heat transfer coefficient as a function of the current heating temperature. These signals are fed to the inputs Y and P of the multiplying-dividing block, and its alternating input ± X receives an amplified signal proportional to the deviation of the differential thermal curve from the zero line. In the multiplying-dividing block the dependence of the form is realized ..

As a result, a voltage appears at its output proportional to the deviation of the differential thermal curve from the zero line, in which its dependence on the change in heat exchange conditions in a wide (more than 300 ° C) heating temperature is more accurately taken into account due to a more accurate piecewise heat transfer coefficient. broken. Integrating the signal from: 1 inlet of the multiplier-dividing block with the absorption of the integrating block, it is possible to obtain a signal proportional to the enthalpy of the sample under study, in the required temperature range.

Thus, the proposed device makes it possible to more accurately take into account in automated data processing the effect of changing the heat transfer conditions of a sample in a wide (more than 300 ° C) temperature range, which increases the enthalpy calculation accuracy and also automatically calculates the differential heat capacity and enthalpy of an enlarged veplity with a convenient opportunity. fixing results on an automatic plotter.

Claims (2)

1.Thermochimica Acta 1974, 8, No. 1-2, p. 3-13. 2.I. R. Williams and W. W. Wendlandt in H. G. Wiedeinan (editor). Thermal Analysis, Birkhaser, Verlag Basel. Vol. By 1972, p. 75