SU1594401A2 - Method and apparatus for differential thermal analysis - Google Patents

Abstract

In order to carry out the differential thermal analysis of an investigation material (2), a material flow (6) of the investigation material (2) is continuously supplied by means of a conveyor (4) to a furnace (7) in order to heat it in the entire temperature range. At the same time as the heating inside the furnace (7), that location of at least one temperature zone (15) along the uniformly conveyed material flow (6) of the investigation material (2) is investigated in which the thermal behaviour of the material flow (6) of the investigation material (2) is measured without interruption by means of a temperature measuring device (thermometer) (12). <IMAGE>

Description

The invention relates to thermography and can be used for continuous phase analysis of substances, mainly for determining the composition of the ore during the exploration and exploitation of mineral deposits.

The purpose of the invention is to improve the accuracy of the analysis and the continuous recording of the thermoelectric effect and its maximum value.

The goal is achieved by the method of differential thermal analysis, which consists in that the sample is transported through a preheated oven with a temperature gradient along its length and the maximum thermal effect values are recorded using a temperature sensor installed in the furnace zone having a temperature of

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thermoelectric effect along a continuously moving sample, perform a reciprocating motion of the thermal sensor and, correcting its amplitude by the magnitude of the thermal effect, keep the thermal sensor in the temperature zone of the furnace corresponding to the thermal effect.

For continuous recording of the thermal effect, the reciprocating movement of the thermal sensor is performed with a maximum amplitude within the thermal effect, changing the direction of movement of the thermal sensor to the opposite when the measured value decreases to the minimum value in the initial and final stages of the thermal effect.

In order to continuously register the maximum value of the thermoelectric effect, the reciprocating motion of the thermal sensor is performed with a minimum amplitude within the thermoelectric effect, changing the direction of movement of the thermal sensor to the opposite for any decrease in the measured value.

A device for differential thermal analysis, containing a gradient furnace with a movable sample carrier, an arcuate thermal sensor and a thermal balancing mechanism .; the sensor further comprises a mechanism for the reciprocating movement of the thermal sensor and a node for adjusting the amplitude of the movement.

Figure 1 shows the thermogram of a substance with continuous measurement of the entire thermoelectric effect zone in the coordinates of the temperature difference - time; Fig. 2 shows a thermogram of a substance with continuous measurement of the maximum value of the thermoelectric effect in the same coordinates in Fig. 3 — a diagram of the proposed device.

The device for differential thermal analysis contains a furnace 1, an arcuate shaped thermal sensor 2, a movable sample carrier 3, a fixed guide support 4, a balancer 5, a reciprocating movement mechanism 6, and a motion amplitude adjustment unit 7.

Differential thermal ana-g

LIZ is carried out as follows.

The analyzed samples are continuously poured into the moving carrier 3 pro-. would. As a result, each sample is filled.

five

0 5

About 5

0 5

0

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There is no specific length of the carrier 3 samples. Along the guiding support 4, the sample carrier 3 continuously and evenly transports the sample through the furnace 1 with a temperature gradient along its length. In this case, the amplitude of movement has a maximum range and covers the entire thermal effect zone. The measurement results are expressed as periodically repeated thermal effects (Fig. 1), which are recorded during both translational and return movements of the thermal sensor 2. In case the thermal effect zone will move along the sample, the reduced operation mode of the motion amplitude adjustment unit provides the proportion shift of the temperature range of the thermal sensor to the thermal effect zone.

If necessary, continuous measurement of the maximum value of the thermoelectric effect of the Uschg 7 amp-correction. The fluids of movement set the mode, with which the direction of movement of the sensor 2 switches, as soon as the measured value decreases. At the same time, the amplitude of the movement has a minimum span, and the thermal sensor 2 is kept in the zone corresponding to the maximum value of the thermal effect, registering in a continuous sequence the maxima of the thermal effects (Fig. 2). Since any displacement of the maximum thermal effect along the sample causes a decrease in T, the node 7 for adjusting the amplitude of movement will shift the thermal sensor 2 to the maximum zone.

The invention provides higher accuracy and reliability of the results due to repeated measurements for each sample by one experiment and due to high productivity can be used for both scientific and industrial purposes.

Thus, different parts of the same sample are heated to different temperatures, and the thermal effect is stretched along the length of the sample in a certain interval. Due to the continuous updating of the sample portion in this interval, the thermal effect does not fade as long as the sample moves. However, there may be cases, for example, with variations in the phase composition of the sample, when the thermal effect changes its temperature and, consequently, its location along the length of the sample.

Using the mechanism of reciprocating motion, the differential thermal sensor 2 is moved along the sample carrier 3, fixing the temperature difference 4 T at each portion of the sample carrier and the corresponding zone of the furnace 1 until the thermal effect thermal zone is detected. Next, the movement amplitude adjustment unit 7 is activated, which changes the direction of movement of the thermal sensor 2 depending on its position in different parts of the thermal effect.

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The correction of the amplitude of movement is carried out as follows.

If it is necessary to continuously measure the entire thermoelectric effect zone, the movement amplitude adjustment unit 7 sets the mode in which the direction of motion of the thermal sensor switches in the initial and final stages of the ternological effect, i.e. switching condition is to reduce the measured value to the minimum

temperaTI 15

meaning (T,), where the tour sample; T is the temperature of the corresponding section of the furnace.

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FIG. g

Claims (1)

C Differential thermal analysis method according to autor.St. No. 1138720, characterized in that, in order to improve the analysis accuracy and continuous recording of the thermal effect and its maximum value, along the continuously moving sample, they perform a reciprocating motion of the thermal sensor amplitude by the magnitude of the thermal effect, keep the thermal sensor in the temperature zone of the furnace corresponding to the thermal effect.