SU549718A1 - Method of temperature equalization of calorimetric chambers - Google Patents

Description

The balance between the chambers with this method is not less than 0.001 degrees.

The drawing explains the proposed method.

The drawing shows a thermal shunt /, a reference chamber 2 with a resistance thermometer 3, heaters 4 and 5, a working chamber 6 with a resistance thermometer 7 and heaters 8 and 9, resistors 10 and 11 of the electric meter bridge, a variable resistor 12, an average regulator 13 temperature of chambers, controller 14 of differential temperature of chambers, electric motor 15, reference current source 16, resistor 17, recorder 18, variable resistor 19.

Resistance thermometers 5 and 7 and resistors 10 and) / are connected in a bridge circuit. A variable resistor 12, the movable contact of which is connected to the shaft of the electric motor 15, is included in the diagonal of the bridge, to which the supply voltage is connected.

The measuring diagonal of the bridge 3, 7, 10, 11 is connected to the input of the differential temperature controller 14, and its output is connected to the heaters 5 and 8, through which equal currents, but oppositely directed currents / o from the current source 16 flow.

In the absence of thermal processes in the calorimetric chambers 2 and 6, the electric measuring bridge 3, 7, 10, 11 is balanced. In the presence of thermal processes in the chambers, the electrical measuring bridge will be unbalanced. According to the imbalance signal, the controller 14 controls the temperature between chambers 2 and b to reduce the imbalance signal to the bullet. At the same time, the output current of the regulator 14 is added to the reference current / o in one chamber and subtracted from / about the other chamber, which causes the corresponding heating of one chamber and cooling of the other. When the sign of the imbalance changes, the direction of the output current of the regulator 14 changes, as a result of which the chambers change places for heating and cooling.

Thus, the controller 16 ensures the constancy of the temperature difference, or the equality of the temperatures between the chambers under different thermal effects on the calorimetric chambers.

The output current of the regulator 14, flowed through the resistor 17, is recorded on the recorder 18. At the same time, the base line (instrument zero) is written. In the presence of thermal processes, the power is recorded on the recorder, which is spent on maintaining the constancy of the temperature difference between the chambers, or the equality of the temperatures between them.

To reveal the temperature difference between the chambers, the latter are interconnected by a thermal shunt / made, for example, from copper, gold or any heat-conducting material. In case of inequality of the temperatures of the chambers, the heat shunt from one chamber to the other will be transferred to the heat flux, which is proportional to the constant temperature difference between the chambers. This heat flux will be recorded on the recorder as a baseline otklopeni. Balancing the electric bridge of the differential temperature controller

reduce the temperature difference between the cameras to zero, reducing the deviation of the baseline to zero.

Temperature equalization between the chambers can be carried out in the entire temperature range of chambers heating, which is provided by the average temperature controller 13, the input of which is connected to the moving contact of the variable resistor 12, and the output to the heaters 4 and 9.

In accordance with the program signal generated on the resistor 12 when the moving contact of the motor 15 rotates it, the controller provides programmed heating of the chambers.

Thus, with this method of equalizing the temperatures of the calorimetric chambers of the decks, the temperatures of the chambers are not lower than 10 ° C versus approximately ° C when the temperatures are equalized.

on the points of fusion of reference points In this case, the zero drift of the instrument, which arises due to the inequality of the temperatures of the working and reference chambers of the DSM, can be reduced to almost zero.

In addition, the proposed method allows the chambers to be balanced by temperature at any point in the temperature range, is simpler and reduces the time taken to equalize the chambers' temperatures.

Claims (2)

1. Heat capacity of linear polymers. M., “Peace, 1972, p. 130., 2. Churnovskiy A. F. Thermophysical characteristics of dispersed materials. M., 1962., p. 150-151 - the prototype. i: