SU540177A1 - Acoustic device for measuring the temperature of the gaseous medium - Google Patents

Description

The invention relates to test and measurement technology and instrumentation, namely, temperature converters, and is intended for use in various kinds of enterprises, in research institutes, design offices and other institutions where it is necessary to record the temperature of gas media, for example products of combustion.

Devices for measuring the temperature of a gaseous medium containing a thermocouple are known to have low accuracy and reliability 1.

Most closely to the present invention, there is an acoustic device for measuring the temperature of the gaseous medium, comprising a resonator and a pressure pulsation sensor mounted therein, connected through an amplifier to the measuring device 2.

The disadvantages of this acoustic device are the comparatively low accuracy and reliability of the obtained results of temperature measurement under high intensity conditions and especially in the presence of discrete components.

The response of the resonator is often poorly distinguishable against the background of a general powerful sound, and the presence of a discrete component in the spectrum of the sound leads to an increase in the level of pulsations.

at its frequency fe the resonator, which does not allow one to accurately determine the temperature in a gaseous medium. The resonant resonator response and its response to a discrete frequency are almost indistinguishable.

The purpose of the invention is the automatic elimination of interfering and spurious signals resulting from the background noise and the presence of discrete components in the noise, and consequently, an increase in the accuracy and reliability of the information obtained during measurements.

This goal is achieved by the fact that the resonator is located inside another resonator with a short eigenfrequency, which is equipped with a pulsation difference sensor in the resonators. Ia drawing schematically shows the proposed device.

The housing 1 of the device has a resonant cavity 2 and ends with a neck 3 in the form of a threaded choke. Inside the case is placed a resonator 4 with an inductive differential sensor for pressure pulsations 5 and a throat 6, which passes coaxally to the throat of the first resonator.

The device works as follows. To measure the temperature, the device is strengthened using fitting 3. The gas flow excites the resonators 2 and 4. At the same time, the resonators simultaneously give a response in the form

pressure pulsations for background noise, discrete noise components and proper resonant pulsations. These pulsations from each resonator act on the membrane of the inductive differential pressure pulsation sensor 5 on different sides. Therefore, at the output of the sensor, the electrical signal from the background noise and discrete components virtually disappears.

The sensor transmits only signals from the resonance in resonators 2 and 4 to the amplifier. The signals “are colored. If the signal from resonator 2 is positive, then from resonator 4 is negative (and vice versa). In this way, the device provides accurate and reliable information about the gas temperature.

Claims (2)

1. Petunin A. N. “Measurement of parameters of gas flows, Mash., M., 1965 2. Avt. swith No. 346604, M.C. G OIL 11/10, 10/19/1950 (prototype).