SU1264012A1 - Method of determining temperature of conducting liquids - Google Patents

Abstract

The invention relates to technical physics, in particular, to methods of ensuring the accuracy and stability of temperature measurements by electrically influencing the characteristics of processes developing in the boundary layer of thermal sensors in contact with a controlled fluid. The aim of the invention is to improve the accuracy of measuring the temperature of electrically conductive liquids using thermistors. The thermistor is placed in a protective metal fitting secured in the instrument case and isolated from it. The resistance value of a thermistor with a measuring current limiting through it is measured. When measuring the resistance between the instrument case and the choke through an electrically conductive fluid, S is passed an electric current with a density of 10 10 A / mm at the choke to eliminate The limits of the measurement current through a thermistor are shown: 1 or 4

Description

The invention relates to technical physics, and in particular to methods for ensuring the accuracy and stability of temperature measurements by electrically affecting the characteristics of processes developing in the boundary layer of temperature sensors in contact with a controlled fluid.

The purpose of the invention is to improve the accuracy of temperature measurement of electrically conductive liquids using thermistors by reducing the error from overheating by electric current from secondary conversion circuits.

The drawing shows the experimental measured dependences of the overheating of thermistors enclosed in a metal nozzle depending on the power dissipated by the thermistors with changing characteristics of the medium under study without additional current transmission 'between the nozzle and the device body and when current is passed.

The power allocated to the thermistor when measuring its resistance in the range of measured temperatures is determined from the relation p '= (ω ’- 10’) P>

⁷ min minute ⁴ g d where P _MCM - passport value of the minimum power dissipation of the thermistor: S _(- shell surface of the working area of the thermistor body;

Sj is the surface area of the protective metal fitting;

A, and A ₂ - thermal conductivity of the liquid air, respectively.

Protective metal probe, EP thermistor perform isolated from the device. According to the experimental data shown in the drawing, it was established that when an electric current with a density of I0 ⁶ - 10 ' ⁵ A / mm ^{1 is} passed between the nozzle and the case of the thermistor during measurement of the resistance of the thermistor, the anomalous overheating of the thermistor at low power dissipation is eliminated.

An alternating current source with a high output resistance can be used as an additional source, or a constant voltage supplied to power the secondary conversion circuit can be used. In the second case, it is preferable to connect the negative pole of the source to the protective fitting through a high-resistance resistor and connect the positive pole to the device body.

Claims (1)

The invention relates to technical physics, in particular to methods for ensuring the liver accuracy and stability of temperature measurements by electing Iec to influence the characteristics of the processes developing in the boundary layer of thermal sensors in contact with the controlled fluid. The purpose of the invention is to improve the accuracy of measuring the temperature of electrically conductive liquids using thermistors by reducing the error from overheating them with electric current from secondary conversion circuits. The drawing shows experimental experimental dependences of the overheating of thermistors 1 enclosed in a metal fitting depending on the power dissipated by the thermistors with varying characteristics of the test medium without additional current flowing between the fitting and housing of the device and current flowing. The power measured by the thermistor when measuring its resistance in the range of measured temperatures is determined from the ratio (10 - o) P ".. - b. where P is the passport value of the minimum power dissipated by the thermal resistor: S, is the surface area of the shell of the working body of the thermal resistor; Sj is the surface area of the protective metallic fitting, A, and A, j are the thermal conductivities of the fluid air, respectively. Protective metal pieces, the thermistor resistors, are isolated from the instrument case. According to the experimental data cited in the drawing, it was established that during the measurement of the resistance of the thermistor between the nozzle and the instrument case of an electric current with a density of 10.-10 / A / mm, an overheating of the thermoresistor at al1.1x power is excluded. x is scattered on it. As an additional source, a alternating current source with a high output impedance can be used, or a direct voltage applied to supply the secondary conversion circuit can be used. In the second case, it is preferable to connect the negative pole of the source to the protective nipple through a high-resistance resistor and connect to the instrument case of the positive pole. The invention The method of determining the temperature of the electric wire sag fluids, consisting in measuring the resistance value of a thermistor placed in a protective metal fitting fixed in the instrument case, with a measuring current flowing through the thermistor, and comparing the measured resistance values with the calibration characteristic, that, in order to improve the measurement accuracy by reducing the error due to overheating of the thermistor by measuring current J when measuring thermistor resistance between the armature pusom device and isolated from it by fitting the electrically conductive liquid is passed from an electrical current density of 1 A - 10 A / mm on the nozzle, and measuring the current through the thermistor within the limit) / -Iia. ..- rlAA, G S, A, - passport value of the minimum dissipation power of the thermistor; g - passport value of the resistance of the thermistor; S - the surface area of the shell of the working body of the thermistor; Sj is the surface area of the protective nippleJ is the thermal conductivity of air and liquid, respectively. tff-ibin fij ffi d7 fi