SU1151836A1 - Remote temperature measuring method - Google Patents

Abstract

A METHOD FOR REMOTE TEMPERATURE MEASUREMENT, which consists in exciting oscillations in a temperature sensitive piezoresonator and determining the temperature by the frequency of vibrations, characterized in that, in order to improve the accuracy of measuring and expanding the range of measured temperatures, vibrations in a temperature sensitive piezoresonator excite with the help of in-line pulse ultrasounds, I went to the temperature gauges I used to use IQTs, I used I-Ipods, I used the Icade gauges, I used the Icade gauges, I used the Icade gauges, I would be using the Icade gauges, I would use the Identity gauges, I would use the Identity gauges, I would use the Identity gauges, I would use the Identity gauges, I would use the Identity gauges, I would be used as I would be using the I-lines, I would be used as I would be using the I-lines, I would go as I would like to use Ipods. receive electromagnetic radiation from a piezoresonator, the frequency of which is judged on the measured temperature.

Description

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The invention relates to temperature measurement, in particular, to methods for remote temperature measurement based on the use of piezoelectric temperature-to-frequency transducers and can be used to measure temperature in hard-to-reach places.

Methods are known for remote temperature measurement based on the use of temperature-sensitive piezoresonators, in which the temperature is converted into the frequency of electro-magnetic oscillations using temperature-sensitive piezoresonators included in the oscillator circuit. Temperature-sensitive piezoresonators are placed at the temperature measurement points and connected to the oscillator via wires l.

When measuring the temperature at several points, the switching wire system becomes complex. In some cases, for example, in measuring temperature in moving or rotating objects, the use of switching wires is difficult. Or it is not at all possible. I

A known method for remote temperature measurement consists in exciting oscillations in a measuring circuit made in the form of a dual-circuit parametric oscillator with non-multiple frequencies and including a temperature-sensitive piezoresonator measuring the oscillation frequency of the measuring circuit and determining the temperature from the oscillation frequency fjZl.

The disadvantage of this method is the necessity of using a measuring circuit, made in the form of a dual-circuit parametric generator with non-multiple frequencies, which leads to: a decrease in the measurement accuracy due to the shunting effect of the circuits of the measuring circuit,

The closest in technical essence to the present invention is a method for remote temperature measurement, which consists in exciting vibrations in a temperature-sensitive piezoresonator and determining the temperature by the frequency of vibrations. Heat-sensitive piezoresonator include in the measuring circuit, containing62

conductive inductance and capacitor. The oscillations are excited in the piezoresonator by means of electromagnetic oscillations. The temperature is determined by the frequency of the electromagnetic oscillations emitted by the measuring circuit 3,

The disadvantage of this method is the necessity of including a piezoresonator in the measuring circuit, which leads to a decrease in measurement accuracy due to the shunting effect of the circuits of the measuring circuit, limiting the range of measured temperatures due to the change of parameters of the elements of the measuring circuit at low and high temperatures. In addition, the presence of the measuring circuit does not allow placing the piezoresonator in hard-to-reach points.

The purpose of the invention is to improve the accuracy of temperature measurement and the expansion of the range of measured temperatures,

The goal is achieved

According to the method of remote temperature measurement, involving excitation of oscillations in a temperature-sensitive piezoresonator and determining the temperature by the oscillation frequency, oscillations in a temperature-sensitive piezoresonator are remotely excited by an ultrasound signal, and after excitation of oscillations, the piezoresonator receives electromagnetic radiation, the frequency of which is measured temperature

The drawing shows the device

to implement the proposed method.

The device contains a temperature-sensitive piezoresonator 1 with a certain frequency of natural oscillations, located on the object whose temperature is measured, an ultrasonic generator 2 with an emitter 3, a receiver 4 of electromagnetic oscillations with an antenna 5, a frequency meter 6, and also a power source 7,

If it is necessary to measure the temperature at several points, several temperature-sensitive piezoresonators are used, each having different frequencies, each of which is fixed at a corresponding point,

The device works as follows. 3 A heat-sensitive piezoresonator 1 is remotely excited by ultrasound from an ultrasonic vibration generator 2. The elastic oscillations of the piezoresonator with a frequency determined by the measured temperature are converted into electromagnetic oscillations, which are radiated into the surrounding space, are received by the antenna 5 of the receiver 4 of the electromagnetic oscillations, amplified and fed to the frequency meter input. With this, the oscillation frequency of the piezoresonator is uniquely related to its temperature. To excite a piezoresonator, a signal generated by an ultrasonic generator must have a component in its oscillation spectrum that coincides in frequency with the resonance frequency of the piezoresonator or close to it. Such a signal can be obtained, for example, by simulating the pulse modulation of a carrier wave with a frequency close to the frequency of the piezoresonator, or by amplitude modulating the carrier wave with a noise signal. The use of the proposed method of remote temperature measurement provides an extension of the range of measured temperatures by about 4 times, from the limits of -60 to + to the limits of -260 tons, increasing the accuracy of measurement and resolution, achieving high reliability and compactness of temperature sensors, as well as placing them in small volumes and hard-to-reach places, simultaneously measuring the temperature at an unlimited number of object points and obtaining a picture of the temperature field, reducing aging of the pyeorezo nator.

Claims (1)

METHOD OF REMOTE TEMPERATURE MEASUREMENT, which consists in exciting oscillations in a thermosensitive piezoresonator and determining the temperature from the oscillation frequency, characterized in that, in order to increase the accuracy of measurement and expanding the range of measured temperatures, the oscillations in the thermosensitive piezoresonator are remotely excited by an ultrasonic signal, and after excitation the oscillations are carried out the electromagnetic radiation of a piezoresonator, the frequency of which is used to judge the measured temperature. (L 9681211>