SU777585A1 - Gaseous and liquid media parameter measuring method - Google Patents

Description

one

 The invention relates to a measuring technique. It can be used to measure parameters (temperature, speed of movement, etc.) in fluid and liquid media in experimental aero-hydrodynamics.

At present, her time is known for mixing parameters of gas and liquid media by placing a semiconductor sensing element into the test medium and heating it from a source. Pita 1 1. The disadvantage of this method is the low accuracy when measuring parameters of static media.

The closest to the invention in its technical essence is a method for measuring the parameters of gas and liquid media, consisting of placing a thermal element that is connected to an electrical circuit in the test medium, passing an electric current pulse through the Negro, measuring the time interval and determining the parameters of the medium from functional limes. addiction m 2.

However, this measurement method is not accurate enough due to the considerable time interval between the moments of measurement of homogeneous parameters of the medium.

The aim of the invention is to improve the accuracy of parameter measurements by measuring during a single pulse.

5 The goal is achieved by creating a rising edge in time of the leading edge of the pulse, fixing the time when the electrical signal at the input of the electrical circuit reaches a value not

10 that provides the heating of the temperature-sensitive element, and the point in time when the electrical signal at the output of the electrical circuit reaches a value corresponding to the input signal, and then the time interval between the fixed moments is determined, then the point in time is recorded when the electrical signal at the input of the circuit reaches providing the heating of the temperature-sensitive element, and the point in time when the electric signal at the output of the circuit reaches a value corresponding to the input signal, and also cases the time interval between registered dissolved

25 points in time.

The invention is illustrated in the drawings, where in FIG. 1 shows a device implementing a method for measuring parameters of gas and liquid media; in fig. 2--

Claims (2)

30 is a respective time diagram. The device contains a temperature-sensitive element 1 connected in series with a capacitor 2 to the input of the generator 3. A method for measuring parameters of gaseous and liquid media is implemented as follows. A circuit t / o is applied to an electrical circuit consisting of a temperature-sensitive element 1 with electrical resistance RT and a capacitor 2 with capacitance C. Output voltage f / out electrical; the circuit will be delayed with respect to the input signal by an amount depending on the constant time t of the circuit: - "and therefore, as can be seen from this relation (1), on the magnitude of the electrical resistance t of the temperature sensitive element 1. At low currents through the temperature sensitive element ( the voltage level f / i) its electrical resistance does not depend on the current and is entirely determined by the temperature of the medium in which the temperature-sensitive element is placed. With increasing current, the thermosensitive element begins to overheat relative to the environment. In this case, its electrical resistance Rt is already determined by the conditions of heat exchange between the temperature-sensitive element and the environment. Consequently, the value of the time constant is also determined by the parameters of the environment. Thus, the magnitude of the constant time t at low current levels (voltage level C / i) through the temperature-sensitive element is determined by the temperature of the medium, and at high current levels (voltage level at the input of the C / 2 circuit) it is the blowing speed. Consequently, the delay of the output signal of the circuit ti compared to the input at low currents in the circuit is determined by the time constant 1 - ;; where is the electrical resistance of the temperature-sensitive element, determined by the temperature of the medium under study, and the delay time tz is determined by the constant time where RT is the electrical resistance of the thermosensitive element determined by its heat exchange conditions with the environment (air flow rate, density, composition, etc.). When an impulse with an increasing front edge increases in time at the input of the electric circuit, recording the delay time of the output signal / 1 and ifa at low and high currents through a temperature-sensitive element determines the temperature of the medium, functionally related to the interval value / ь and movement speed ( density, composition, etc.) of the medium, functionally related to the value of the interval t. This allows for the measurement of two parameters of the medium at once during the action of a single input pulse, thereby reducing the time interval between the moments of monitoring the uniform parameters of the medium. The method of measuring parameters of gaseous and liquid media, consisting in placing a temperature-sensitive element included in an electrical circuit into a test medium, passing electric current pulses through it, measuring time intervals and determining environmental parameters using known functional dependencies, characterized in that the purpose of increasing the measurement accuracy of the parameters by measuring over the course of a single pulse, the rising edge of the pulse is created, The time point when the electrical signal at the input of the electrical circuit reaches a value not providing heating of the temperature-sensitive element, and the time point when the electrical signal at the output of the circuit reaches the value corresponding to the input signal is measured, and then the time interval between the fixed moments is determined, then the time is recorded the time when the electrical signal at the input of the circuit reaches the value that provides heating of the temperature-sensitive element, and the time when the electrical signal al reaches the output circuit corresponding to the input signal value, and also determine the time interval between the time instants registered. With the accession of the application number 2574628 / 18-10., Sources of information taken in. attention in the examination 1.Ferents V. A. Semiconductor pipe-based thermal thermo-anemometers. M., “Energie, 1972, p. 30-31. 2. USSR author's certificate on the factory No. 2497512 / 18-10, cl. G 01 P 5/12, 17.06.77 (prototype). iBta / Si ,, and,: .- rO -tf U ..