SU1723463A1 - Device for measuring temperature - Google Patents

Abstract

The invention relates to thermometry and allows for improved temperature measurement accuracy. In the steady-state thermal mode, the temperature of the controlled medium and the temperature of the heat-sensitive piezoresonator 1 are equal. The temperature of the thermistors 8 and 9 is equal to the medium temperature, the electric bridge 7 is balanced, and the control voltage at the output of the differential amplifier 12 corresponds to the frequency of the reference oscillator 5. When the medium temperature changes, the resistance difference of the thermistors 8 and 9 causes the unbalance of the electric bridge 7, and at the output of the differential amplifier 12 appears as a signal proportional to the change in temperature of the medium. 1 il.

Description

The invention relates to a measuring technique, namely, temperature measuring means, in which a thermosensitive quartz resonator is used as a sensitive element, and is intended to measure the temperature of a liquid and a gas in pipelines of hydrogasdynamic systems.

A device for temperature measurement is known, which contains a temperature-sensitive piezoresonator connected to a measuring oscillator having a frequency control element, a differential frequency shaping device, a reference oscillator, a recorder, a differential amplifier, to the input of which the piezoresonator electrodes are connected, and the output is connected to a frequency control element.

A disadvantage of the known device is the low measurement accuracy.

The closest to the present invention is a temperature measuring device containing a temperature-sensitive piezoresonator placed in a protective capsule and included in the frequency-setting circuit of the measuring auto-oscillator connected to the first input of the differential frequency generator, the second input of which is connected to the output of the reference auto-oscillator and the output connected to the recorder, a bridge circuit with two film thermistors, one of which is placed on the surface of the heat-sensitive piezoresonator outside the zones active vibrations, and the other - on the outer surface of the protective capsule, wherein the film thermistors are connected in adjacent arms of the bridge circuit, the measuring diagonal which is connected to the inputs of the differential amplifier.

The disadvantages of the known device for measuring temperature are relatively low accuracy due to the instability of the frequency-control element, as well as low reliability due to the placement of one thermal seals on the outer surface of the protective capsule exposed to high-speed flows of the controlled medium.

The purpose of the invention is to improve the measurement accuracy while increasing the reliability of the device.

The goal is achieved in that a temperature measuring device containing a temperature-sensitive piezoresonator placed in a protective capsule and included in the frequency-setting circuit of the measuring auto-oscillator connected to the first input of the differential frequency generator, the second input of which is connected to the output of the reference auto-oscillator, and the output connected to the recorder, a bridge circuit with two thermistors connected to its adjacent shoulders and a differential DC amplifier with inputs connected cheny to the measuring diagonal of the bridge circuit by introducing an additional protective capsule, in the center of the cavity wherein the first thermistor is placed, as the second thermistor is mounted on its inner surface, wherein the geometric dimensions are selected from capsules zaschmtnyh ratios

RD ° 1 Kl. K2 Zl, t ddp gpk

where Rdop, gpdop, FK, GLK, respectively, the area of the inner surface and the mass of the additional protective capsule and the capsule of the temperature-sensitive piezoresonator;

Kch - coefficient taking into account thermal and geometric parameters

thermosensitive piezoresonator and the first thermistor;

Ka is the coefficient taking into account the thermal parameters of protective capsules, and the reference oscillator is equipped with a frequency control element connected to the output of the differential amplifier.

The drawing shows a diagram of a device for measuring temperature.

The device contains a temperature-sensitive piezoresonator 1 placed in a protective capsule 2 and included in the frequency-setting circuit of the measuring auto-oscillator 3 connected to the first input of the differential frequency frequency generating unit 4,

the second input of which is connected to the output of the reference autogenerator 5, and the output is connected to the recorder 6, a bridge circuit 7 with two thermistors 8 and 9 connected to its adjacent shoulders, a differential DC amplifier 10, the inputs of which are connected to the measuring diagonal AB of the bridge circuit 7 , and an additional protective capsule 11.

In the center of the cavity, an additional protective capsule 11 made of a material with high thermal conductivity is placed first, the thermistor 8, and on its inner surface is fixed with the help of heat-conducting glue 12 the second

thermistor 9.

The reference oscillator 5 is equipped with a frequency control element 13 connected to the output of the differential amplifier 10.

Thermistors 8 and 9, bridge circuit 7, differential amplifier 10 and frequency control element 13, included in the circuit of the reference oscillator 5, form a temperature correction circuit of the reference oscillator 5.

The temperature measuring device operates as follows.

In the steady-state thermal regime, the temperatures of the controlled medium and the temperature of the temperature-sensitive piezo-resonator 1 are equal. The temperature of thermistors 8 and 9 is also equal to the temperature of the medium, and the bridge circuit 7 is balanced and the control voltage at the output of the differential amplifier 10 corresponds to the frequency of the reference oscillator 5, equal to f0.

In this case, the frequency of the piezoresonator 1 and, therefore, of the measuring oscillator 3 is determined by the thermal frequency characteristic of the piezoresonator.

As a result, the frequency F of the signal at the output of the differential frequency forming unit 4 is a function of the monitored temperature T.

F fo-fu (T). (1)

where fo is the frequency value of the reference oscillator; .

fu (T) is the current value of the frequency of the measuring oscillator, as determined by the TCh of the temperature-sensitive generator.

When used as a resonator of a piezoquartz LC slice, which has almost linear TCHC, and with slow changes of T, when its change does not exceed 3 Tp (Tn is the time constant of the temperature-sensitive piezoresonator in the protective capsule), dependence (1) can be represented by the equation

F f0- f40 + Kn (T-To) (2)

where T0 - 0 ° C;

fuo is the frequency of the measuring generator signal at

Kn is the steepness of the characteristics of the thermo-sensitive piezoresonator.

When a step change in the temperature of the controlled medium, the change in the frequency of the measuring oscillator must take place exponentially (in accordance with the change in the frequency of the sensitive element):

(1-ef, (3)

where fny is the steady-state frequency of the measuring oscillator.

The temperature of the second thermistor 9, located on the inner surface of the additional protective capsule 10, will have a value equal to

temperature controlled environment, due to the presence of good thermal contact, high thermal conductivity of the material and low mass of the capsule.

The temperature of the first thermistor 8 and, accordingly, its resistance will also vary exponentially

(T) e, (4)

where Ry (T) is the steady-state value of the resistance of the thermistor 8, determined by its thermophysical parameters;

the time constant of thermistor 8 in the additional protective capsule.

Since the temperatures of thermistors 8 and 9 will differ, the difference of their resistances will cause imbalance of bridge circuit 7 and the differential voltage at the inputs of differential amplifier 10 causes a control voltage at its output proportional to the temperature difference. This will lead to a corresponding change in the frequency of the reference oscillator 5 and its value will be determined by the expression

fo foo ± H (T2-Tl), (5)

where foo is the frequency value of the reference oscillator in steady state;

 the steepness of the characteristic of the temperature correction circuit of the frequency of the reference oscillator;

T2Ti is the temperature difference between thermistors 8 and 9. The sign of the second term in expression (5) is determined by the sign of the temperature gradient between thermistors 8 and 9.

In the general case, the frequency at the output of the block and the formation of the difference frequency will be determined by the expression:

Ffoo ± K (T2-TiHfuo + Kn (T-T0); |. (6) Component Kn (T-To) determines the change in the information frequency F due to the change in temperature of the temperature-sensitive piezoresonator 1, and component Kt (T2- Ti) takes into account the presence of a temperature gradient between thermistors 8 and 9, the value of which depends on the amplitude of the change in the controlled temperature and the time elapsed after its change.

The time constant of the temperature correction circuit of the frequency of the reference oscillator 5 is completely determined by the constant time of the thermistor 9. By selecting the appropriate coefficient Kt, you can obtain information about controlled temperature with high accuracy and high speed. In this case, the inertia of the entire device will be comparable to the inertia of the thermistor 9.

In the proposed temperature measurement device, the accuracy of the temperature correction of the frequency of the reference oscillator 5 is ensured by the heat transfer conditions for the thermistor 8 placed inside the additional protective capsule 1.1, the heat transfer conditions for the thermosensitive piezorezonator 1 placed in the protective capsule 2.

To fulfill these requirements it is necessary to fulfill the conditions

Tkv TTP / -yj

Tk - Tdop

where gq is the time constant of the temperature-sensitive piezoresonator 1;

gtr-constant of thermistor 8;

Ik is the time constant of the protective capsule 2 of the thermosensitive piezoresonator 1;

Tcd is the time constant of the additional protective capsule 11.

 In the proposed temperature measuring device, this is achieved by selecting the geometric dimensions of the protective capsules 2 and 11 from the relationship:

Rdop

GPdop

 Ki

where rdop. ppdop FK, tk-respectively, the area of the inner surface and the mass of the additional protective capsule and the capsule of the temperature-sensitive piezoresonator;

Well O-tr P1kv gdr

Ct

OGkv GPtr FKB coefficient

ent, taking into account the thermophysical and geometrical parameters of the thermosensitive piezoresonator 1 and the first thermistor 8;

Sdop & k

K2

 - coefficient taking into account &

thermal parameters of protective capsules 2 and 11;

Ske, pp. Sdop, Ck - respectively, the specific heat capacity of the temperature-sensitive piezoresonator, the first thermistor, the additional protective capsule and the capsule of the temperature-sensitive piezoresonator;

"Q, 2Tp, Odop," k-, respectively, the heat transfer coefficient of the temperature-sensitive piezoresonator, the first thermistor, the additional protective capsule and the capsule of the temperature-sensitive piezoresonator;

0

five

0

five

0

five

0

five

0

FKB, gpkv, Rtr, Shtr, respectively, the active surface area and the mass of the temperature-sensitive piezoresonator and the first thermistor.

The proposed device for measuring temperature makes it possible to increase the accuracy by eliminating the influence of the environment on the parameters of the frequency control element included in the reference oscillator circuit and included in the temperature correction circuit of the reference oscillator frequency, while simultaneously increasing the reliability of the second thermistor. inside an additional protective capsule, which reduces the impact on him of the flow of the controlled medium.

F o rm u l a i z o 5 p e te n u

A temperature measuring device containing a temperature-sensitive piezoresonator placed in a protective capsule and included in the frequency-setting circuit of the measuring auto-oscillator connected to the first input of the differential frequency generator, the second input of which is connected to the output of the reference auto-oscillator, and the output connected to the recorder, two thermistors, included in its adjacent arms, and a differential DC amplifier, the inputs of which are connected to the bridge diagonal measurement circuit, characterized in that, in order to improve measurement accuracy while simultaneously increasing the reliability of the device, an additional protective capsule is inserted in it, in the center of the cavity of which the first thermistor is placed, and the second thermistor is fixed on its inner surface, while the geometric dimensions of the protective capsules are chosen from ratios

Rdop ". . „FK

five

 Ki

 KPPK FK, GPK GPdop

where Rdop, pdop,, tk - respectively, the area of the inner surface and the mass of the additional protective capsule and the capsule of the temperature-sensitive piezoresonator;

Ki is the coefficient taking into account the thermal and geometrical parameters of the thermosensitive piezoresonator and the first thermistor;

K2 is the coefficient taking into account the thermal parameters of protective capsules, and the reference oscillator is equipped with a frequency control element connected to the output of the differential amplifier.

Claims (1)

Claim A device for measuring temperature, containing a thermosensitive piezoresonator placed in a protective capsule and included in the frequency-setting circuit of the measuring oscillator connected to the first input of the differential frequency generating unit, the second input of which is connected to the output of the reference oscillator, and the output is connected to the recorder, a bridge circuit with two thermoresistors , included in its adjacent shoulders, and a differential DC amplifier, the inputs of which are connected to the measuring diagonal of the bridge circuit s, characterized in that, in order to increase the measurement accuracy while increasing the reliability of the device, an additional protective capsule is inserted into it, in the center of the cavity of which the first thermistor is placed, and a second thermistor is fixed on its inner surface, while the geometric dimensions of the protective capsules are selected from relations = Κι Kr - GPdop ΠΊκ where gdop, GPdop, F _K , m _K are the surface area and mass of the additional protective capsule and the thermosensitive piezoresonator capsule, respectively; Κι - coefficient taking into account the thermophysical and geometrical parameters of the thermosensitive piezoresonator and the first thermistor; Kg is a coefficient that takes into account the thermophysical parameters of the protective capsules, and the reference oscillator is equipped with a frequency-controlling element connected to the output of the differential amplifier. piezoresonator;