SU1647283A1 - Method of measurement of stationary gas temperature - Google Patents

Abstract

The invention relates to a measurement technique and makes it possible to improve the accuracy of measuring the temperature of gases by contact thermopiles. For this, a thermopile - thermocouple is periodically brought into oscillatory motion in a gas medium and heated by alternating current until then. until the thermocouple temperature reaches the stationary gas temperature. The indicated moment is fixed by the coincidence of the readings of the measuring device in the oscillatory motion of the thermocouple and when the thermocouple is at rest. 1 il.

Description

The invention relates to a measuring technique and can be used in systems for measuring the temperature of gases by means of contact thermal receivers.

The purpose of the invention is to improve the accuracy of measuring the gas temperature.

The drawing shows a block diagram of a device that implements the proposed method for measuring gas temperature.

The device comprises a thermocouple 1, an electronic potentiometer 2, for example, a KSP-4 type, a low-pass filter 3, an electromechanical actuator 4, a regulating device 5, a frequency generator 6, a power amplifier 7 and a coupling condenser 8.

The method is carried out as follows.

First, an electronic potentiometer 2 records the temperature t, e sp of the fixed thermopair 1 located in the gas channel, the temperature of the walls of which is lower than the measured stationary gas temperature t. Then thermocouple 1 using

The electromechanical actuator 4 is brought into oscillatory motion with a sufficiently high frequency and the temperature of the thermocouple spades 1 is again recorded by the electronic potentiometer 2, which takes on a new value of t greater than the previous value of temperature t3. An increase in the thermocouple 1 thermocouple temperature during its movement is caused by an increase in the heat transfer coefficient, which increases with an increase in the oscillation frequency of thermocouple 1. After that, the electromechanical actuator 4 is disconnected and, when the thermocouple spa temperature 1 decreases at rest, the thermocouple 1 is heated by alternating current by means of a regulating device 5 which changes the amplitude of the alternating voltage of the ultrasonic frequency of 20 kHz supplied from the generator 6 to the power amplifier 7. until. until thermocouple 1 at rest is heated to its previous temperature ta. which she had in terms of cola (L

WITH

about

Xi

Yu

00

00

ballet movement. A low-pass filter 3 connected at the input of the electronic potentiometer 2 provides for the separation of the useful signal of the thermo-ED C of the thermocouple 1 from the alternating heating voltage of 20 kHz. The separation capacitor 8 eliminates the shunting of the thermocouple 1 at a constant current.

After heating the thermocouple 1 with alternating current under conditions while it is again brought into oscillatory motion by an electromechanical actuator 4. At the same time, the temperature of the thermocouple 1 rises again to a new value of 1e, a higher value of i.e. Then, the electromechanical actuator 4 is switched off again and, when the temperature of the thermocouple spa 1 decreases at rest to ts, the thermocouple 1 is reheated until its temperature reaches the previous temperature t3, which was in oscillating conditions.

The described cycle of step heating of thermocouple 1 is repeated until the spa temperature of thermocouple 1 coincides within the error of the electronic potentiometer 2 with the previous temperature of thermocouple spa 1 heated under conditions

rest. In this case, the temperature of thermocouple 1 is assumed to be equal to the desired stationary temperature t of gas. Practically, three or four thermocouple preheating cycles are enough to achieve such a match.

Claims (1)

The method of measuring the stationary temperature of a gas, which consists in placing a thermal receiver in a controlled gas environment, heating the thermal receiver with an alternating current, bringing it into oscillatory motion and recording the temperature of a thermal receiver, characterized in that, in order to improve the accuracy of measurement, after recording the temperature of the thermal receiver, it is stopped and additionally heated to a temperature coinciding with the temperature recorded during the oscillatory motion of the thermal receiver, and the decree nnye action constituting the measurement cycle is repeated until the coincidence termopriemnika temperature values in the two consecutive measuring cycles, kstoruyu taken for gas temperature. j da , t