SU1087865A1 - Electrochemical gas analyzer - Google Patents

Abstract

An ELECTROCHEMICAL GAS ANALYZER, comprising a housing with electrolyte and electrodes, a thermal compensation circuit consisting of thermo-independent and thermo-dependent parts, and a load, characterized in that, in order to improve the measurement accuracy with increasing measuring range of operating temperatures, parallel to the thermo-dependent part of the thermal compensation circuit, series-connected n, i, and resistor and thermistor, in parallel with which the load is turned on. CX CX5 C71

Description

The invention relates to gas analytical instrumentation and can be used to improve the measurement accuracy of devices whose output signal increases with increasing ambient temperature, i.e. having a positive temperature fault. A gas analyzer is known, consisting of a sensor and a measuring unit. The sensor includes a galvanic cell and a thermal resistance installed in a common hermetic organic glass case 1. The disadvantage of this gas analyzer is that the thermal resistance is not included in the measuring circuit of the sensor, and taking into account the temperature effect of the galvanic sensor is performed analytically or graphically after a preliminary temperature measurement. the environment. The closest in technical essence to the invention is an electrochemical gas analyzer, comprising a housing with electrolyte and electrodes, a thermal compensation circuit consisting of thermo-independent and thermo-dependent parts, and a load 2. However, due to small values of temperature coefficients of resistance changes of existing thermistors, compared to with temperature coefficients of change in the output signal of the electrochemical primary converter; 1 cannot be obtained using this circuit with the required temperature There is a great deal of sensation, and consequently, measurement accuracy with an increase in the range of variation of the working temperatures of gas analyzers. The aim of the invention is to improve the measurement accuracy with increasing range of measurement of operating temperatures. The unallocated goal is achieved by the fact that in an electrochemical gas analyzer, comprising a housing with electrolyte and electrodes, a thermal compensation circuit consisting of thermo-independent and thermo-dependent parts, and a load parallel to the thermostable dependent thermal compensation circuit is connected, containing a series-connected variable resistor and a thermistor, in parallel with which load The drawing shows a diagram of the electrochemical gas analyzer. The device comprises a housing 1 with electrolyte 2 located therein and electrodes 3 and 4, between which the thermal compensation circuit is connected, containing thermo-independent 5 and thermo-dependent 6 parts. Parallel to the latter, a circuit is connected comprising a series-connected variable resistor 7 and a thermistor 8. Load 9 is connected parallel to the thermistor 8. In the presence of the analyzed gas between electrodes 3 and 4, a current arises that creates a voltage drop across all elements connected between them. The magnitude of this current significantly depends on the change in ambient temperature. For example, as the ambient temperature increases, the signal between the electrodes increases at a constant load. However, a thermo-dependent part of the thermal compensation chain is included in the load circuit, which decreases its resistance with increasing temperature. As a result, the voltage drop decreases on this part of the circuit, but this decrease due to the insufficient steepness of the temperature characteristic of the thermistor included in the temperature-dependent part of the value does not ensure full temperature compensation of the signal at the load as the temperature range increases. The partially compensated signal is fed to the variable resistor 7 and thermistor 8, which also reduces its resistance with increasing temperature. There is a further reduction in the voltage across this part of the circuit to the initial level, i.e., to a level that was before the ambient temperature rose. The load 9 is connected parallel to the thermistor 8, therefore, the voltage drop across it remains also valid, independent of the change in ambient temperature. When the ambient temperature decreases, reverse processes occur: a signal is sent between the electrodes, but the size of the thermistors increases, as a result of which the initial voltage is maintained; 1 voltage drop and measurement accuracy increases. An increase in the resistance of the non-transient resistor 7 leads to an increase in the voltage drop across it and, consequently, to a decrease in the useful signal at the load 9, which will be compensated for by increasing the operating temperature range of the gas analyzer. With a further increase in the operating temperature range, it is necessary to further increase the value of the variable resistor 7. As a load 9, a DC amplifier can be used, to the output of which a measuring device or recorder is connected. Studies of twelve prototypes of electrochemical gas analyzers confirmed the measurement accuracy in the range of 0-40 ° C. If without a variable resistor 7 and thermistor 8, the voltage drop at load 9 changed by 8-10% for every 10 ° C in the temperature range O-40 ° C, then with the introduction of elements 7 and 8, the change in voltage drop at the load did not exceed .1.5% when the ambient temperature changes to the same 10 ° C. At the same time for all about-use of the invention will allow

The samples used the same zhevypuskat obshakhtatnye and miningnatives of the variables of the variable resistor 7th gas analyzers of high accuracy

and thermistor 8. that will provide improved labor protection.

1087865d

Claims (1)

An electrochemical gas analyzer containing a housing with an electrolyte and electrodes, a thermal compensation circuit, consisting of thermally independent and thermally dependent parts, and a load, characterized in that, in order to increase the measurement accuracy by increasing the measuring range of operating temperatures, a circuit is connected in parallel with the thermal-dependent part of the thermal compensation circuit; a variable resistor and a thermistor connected in parallel with which the load is connected. QO oo Cn>