SU1571424A1 - Apparatus for measuring instantaneous values of pulsating temperatures of flows - Google Patents

Abstract

The invention relates to temperature measurements and allows for improved measurement accuracy. The signal from measuring bridge 2 with wire thermistor 1, slightly overheated relative to the flow temperature, through amplifier 6, low-frequency filter 9, which separates the low-frequency component of the signal, and variable resistor 10, are fed to the input of adder 11. The signal from the output of differential amplifier 7, connected to the measuring bridge 2 and the output of the adder 11, enters the supply diagonal of the measuring bridge 2 and ensures the maintenance of a constant temperature difference between the flow and the thermistor 1. 2 Il.

Description

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The invention relates to temperature measurements and can be used to measure the rapidly changing temperature of a gas or liquid stream. The purpose of the invention is to improve the measurement accuracy.

Dmr.l shows a block diagram of a device; figure 2 - diagram of his work.

The device contains a wire thermistor 1, for example, a tungsten filament included in the lower leg of the measuring bridge 2, which includes a resistance store 3 and fixed resistors 4, 5, variable gain amplifier 6, differential amplifier 7, current source 8, filter 9 low frequencies with adjustable cutoff frequency, variable resistor 10, adder 11 and the recorder 12.

The device works as follows.

Measuring bridge 2 with a thermistor 1 is connected to the source 8 current through the output resistance of the filter 9 low frequencies. Before measuring the temperature by the current source 8 and the resistance box 3, a current of such magnitude is installed in the thermistor 1 so that it does not feel the flow velocity. This is possible when the temperature of the thermistor is slightly above the flow temperature.

Suppose that the flow temperature changes randomly (Fig. 2, line 1}. The thermistor is placed in the flow. Under the effect of a change in the flow temperature, the temperature and resistance of the thermistor begin to change. The change in resistance of the thermistor is converted into an electrical signal change. Passage through the Low Pass Filter 9, the electrical signal loses the high frequency component of the ripple. After the filter 9, the low frequency signal is fed to the lower branches of the measuring bridge 2 and for the sum OR 11 where it is summed with the signal from the measuring bridge. The output of differential amplifier 7 is formed by a signal proportional to the high-frequency and low-frequency component by the flow of temperature fluctuations. To eliminate the influence of flow rate on termorechistor necessary that

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if the difference between the temperature of the flow of the thermistor and the flow was always small. To fulfill this condition, the signal from the output of the differential amplifier enters the top of the supply diagonal of the measuring bridge 2. In this case, high-frequency current changes occur in the thermistor 1, which maintain the conductor temperature (Aig, 2, line 2), proportional to the low-frequency changes in the flow temperature ( 2, line 3). Thus, the temperature of the thermistor is changed at a lower frequency than the flow temperature, and the temperature of the thermistor is always higher than the flow temperature. The recorder 12 captures a signal proportional to the instantaneous values of the flow temperature.

Claims (1)

Invention Formula A device for measuring the instantaneous values of the pulsating temperatures of the flows, containing a wire thermistor included in the measuring bridge arm, the first top of the power diagonal of which is connected to the output of the differential amplifier and the recorder, and the second one food diagonal is connected via ne " A belt resistor with the first input of the adder, the second input of which is connected to the first vertex of the measuring diagonal of the measuring bridge, the second top of the measuring diagonal of which is connected to the first input of the differential amplifier, the second input of which is connected to the output of the adder, an amplifier with adjustable gain and a current source different to that that, in order to improve the measurement accuracy, a low-pass filter was inserted in it, the output of which is connected to the second vertex of the power diagonal of the measuring cell This input is connected to the output of the amplifier with adjustable gain, the first input of which is connected to the second vertex of the measuring diagonal of the measuring bridge, and the second input is connected to the common bus of the device connected to the common output of the low-pass filter and the first output of the current source, the second output of which connected to the first vertex of the diagonal of the power of the measuring bridge. T, time FIG. 2