RU2349886C1 - Pressure measurement method and device - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: method consists as follows. Pressure cell is inserted into the analysed medium with temperature sensor arranged on the pressure cell. Output signals of the pressure cell and temperature sensor data are recorded. These signals indicate medium pressure. Analysed medium is exposed to generated mechanical vibration at frequency exceeding potential vibration frequency of working medium pressure. Variable signal of preset mechanical vibration frequency is derived from output signal of the cell. This signal and output signals of the cell and temperature sensor indicate diagnostic functions, nominal deviation of which show pressure measurement error. Device consists of piezoelectric element 1, pressure cell 2, temperature sensor 3, band-pass filter 4, amplifier 5, rectifier 6, two-channel analogue-to-digital converter 7 and microcontroller 8. The first microcontroller lead is connected to leads of ADC 7 digital interface and the output of the temperature sensor, the second microcontroller lead is connected to the input of piezoelectric element. The output of the pressure cell is connected to the first ADC input and additionally connected to the input of band-pass filter with its output series connected to the amplifier, rectifier and the second ADC input.

EFFECT: extended application.

2 cl, 1 dwg

Description

The invention relates to measuring technique and can be used to measure the pressure of liquid and gaseous media.

A known pressure meter, the circuit of which is given in the description of the use of the "sigma-delta" ADC of ANALOG DEVICE ("Integrated Circuits: Microcircuits for Analog-Digital Conversion and Multimedia". Issue 1-M, DODEKA, 1996, p.278- 280). A method of measuring pressure is to place a pressure sensor based on a strain gauge bridge in the medium under study, register the output signal of the bridge and determine the medium pressure from this signal. The device consists of a voltage source, a strain gauge bridge, a sigma-delta ADC and a microcontroller.

The disadvantage of this method and device is the lack of correction of the additional temperature error of pressure measurement caused by a change in the parameters of the strain gauge bridge from a change in its temperature.

A device for measuring pressure is also known (patent RU No. 2196970, 7 G01L 9/04, claimed. 02.21.2001, published. 01.20.2003). The method of measuring pressure consists in placing a pressure sensor based on a strain gauge bridge and a temperature sensor in the test medium, adjusting the bridge output signal, registering the corrected bridge signal and the temperature sensor output signal, and determining the pressure of the medium from these signals. The device consists of a voltage source, a strain gauge bridge, a temperature gauge of a strain gauge bridge, a temperature corrector, an ADC, a microprocessor, and read-only memory.

The disadvantage of this method and device is the additional operation of adjusting the output signal of the bridge and the corresponding device (temperature corrector), which leads to an additional error in the measurement of pressure and unnecessarily complicated device.

Also known is a pressure to electric signal converter (certificate RU No. 19324, 7 G01L 9/04, application form 03.01.2001, publ. 08.20.2001). The method of measuring pressure is to place a pressure sensor based on the strain gage bridge in the medium under study, register the output signal of the bridge, generate a signal whose value is affected by a change in the total resistance of the strain gage bridge due to a change in its temperature, registration of this signal, and determination of the medium pressure from these signals. The device consists of a voltage source, a strain gauge bridge, a model resistor, a two-channel ADC, a processor, and read-only memory. The outputs of the measuring diagonal of the strain gage bridge and the outputs of the reference resistor are connected to the first and second differential inputs of the ADC.

The disadvantage of these methods and devices is the lack of current diagnostics of the parameters of the strain gauge bridge, which worsen with time, which leads to an increase in the error of pressure measurement. This diagnosis is especially necessary for hazardous technological industries (for example, for nuclear plants), where failure of the sensor at the wrong time can lead to large financial costs and a threat to production safety. The presence of current diagnostics of the error of pressure measurement allows us to predict the failure of the sensor and replace it in a timely manner.

Closest to the technical nature of the claimed method and device is a method and device for measuring pressure (patent RU No. 2304762, 7 G01L 9/04, claimed. 30.03.2006, publ. 20.08.2007). The method of measuring pressure consists in placing a pressure sensor based on the strain gauge bridge in the test medium, registering the output signal of the bridge, registering a signal corresponding to the temperature of the strain gauge bridge, determining the medium pressure from these signals, placing the temperature gauge on the pressure gauge of the strain gauge bridge, generating a signal corresponding to the general the resistance of the strain gage bridge, this signal and the output signals of the bridge and temperature sensor determine the function of the diagnosis tics, by the deviation of which from the nominal value they judge the error of pressure measurement.

In a device for measuring pressure containing a voltage source, a strain gauge bridge, a model resistor, a two-channel ADC, a microcontroller, a temperature gauge of a strain gauge bridge, a strain gauge bridge is connected in series through a model resistor to a voltage source, the outputs of the measuring diagonal of the strain gauge bridge are connected to the first differential inputs of the ADC, the digital interface of the ADC is connected to the first terminals of the microcontroller, the terminals of the temperature sensor are connected to the second terminals of the micro rocker controller, the strain gauge bridge power leads are additionally connected to the second differential inputs of the ADC, the leads of the reference resistor are connected to the differential inputs of the ADC reference voltage.

The disadvantage of this method and device is the limited scope: the method and device can only be used for pressure sensors made on the basis of a strain gauge bridge, and also with more complex designs of the pressure gauge, changing the parameters of the pressure transmission mechanism to the measuring membrane where the strain gauge bridge is located, will not affect the value of the diagnostic function.

The technical task of the invention is to expand the scope of the method and device for measuring pressure, with the function of self-diagnosis.

The goal is achieved by the fact that in the method of measuring pressure, which consists in placing the pressure sensor in the test medium, placing on the pressure sensor a temperature sensor, recording the output signals of the sensor and the temperature sensor, determining from these signals the pressure of the medium, according to the invention, mechanical vibrations are generated in the test medium with a frequency greater than the possible oscillation frequency of the working pressure of the medium, an alternating signal with the frequency of the specified mechanical vibrations is isolated from the sensor output signal d, amplify, rectify and register this signal, this signal and the output signals of the sensor and temperature sensor determine the diagnostic function, by the deviation of which from the nominal value they judge the error of pressure measurement.

In the device for measuring pressure containing a pressure sensor, a temperature sensor, a two-channel analog-to-digital converter (ADC), a microcontroller, the output of the pressure sensor is connected to the first input of the ADC, the terminals of the digital interface of the ADC and the output of the temperature sensor are connected to the first conclusions of the microcontroller, according to the invention a piezoelectric element located in the test medium near the pressure sensor, a bandpass filter, an amplifier and a rectifier, while the input of the piezoelectric element is connected to the second A output of the microcontroller, the sensor output is connected further to the input of a bandpass filter whose output is connected in series with an amplifier, rectifier, and a second input of the ADC.

Introduction to the method of pressure measurement of the operations of forming and measuring variable pressure (used as a reference for diagnostics), calculation of the diagnostic function as a function of only a change in the result of measuring variable pressure as a function of time and independent of the influence of temperature and measured pressure on this result allows diagnosing by diagnostic functions from the nominal value, change the pressure measurement error and timely replace this pressure sensor.

A feature of the claimed invention is the introduction to the method of measuring pressure of additional operations of forming a variable pressure, extracting from the output signal of the sensor signal a signal corresponding to a given variable pressure, amplifying, rectifying and registering this signal, calculating a diagnostic function. A piezoelectric element, a bandpass filter, an amplifier, a rectifier are additionally introduced into the device and the connections between the elements are changed.

The invention is illustrated by the functional diagram of the device (see drawing).

The device consists of a piezoelectric element 1, a pressure sensor 2, a temperature sensor 3, a band-pass filter 4, an amplifier 5, a rectifier 6, a two-channel ADC 7 and a microcontroller 8. The first outputs of the microcontroller are connected to the terminals of the digital interface of the ADC 7 and the output of the temperature sensor 3, the second output microcontroller 8 is connected to the input of the piezoelectric element 1. The output of the pressure sensor 2 is connected to the first input of the ADC 7 and is additionally connected to the input of the bandpass filter 4, the output of which is connected in series with the amplifier 5 rectifier 6 and the second input of the ADC 7.

The invention is as follows.

The measured pressure acts on the pressure sensor 2, changing its output signal. Registration of the sensor output signal consists in converting this signal to the Nr code and storing this code in the microcontroller 8.

The formation of mechanical vibrations in the studied medium is carried out by applying to the input of the piezoelectric element 1 located near the pressure sensor, electrical pulses from the output of the microcontroller 8 (using, for example, the output of the comparison circuit of the microcontroller 8). The frequency of the pulses is generated in software in such a way as to exceed the maximum possible frequency of pressure fluctuations of the investigated medium and not to go beyond the passband of the pressure sensor 2 itself.

The output signal of the sensor 2, containing information on the working pressure of the test medium and the variable reference pressure, is fed to the first input of the ADC 7 and to the input of the band-pass filter 4. Since the frequency of the variable pressure exceeds the maximum possible frequency of pressure fluctuations of the studied medium, the signal corresponding to the variable pressure and arriving at the first input of the ADC 7, it is usually filtered out using hardware and software in the process of converting the signal into a code and in the Nr code the measured working pressure of the medium is not utstvuet. In contrast, at the output of the bandpass filter 4 there is only a signal corresponding to an alternating pressure. After amplification and rectification, this signal is fed to the second input of the ADC 7, in which, after conversion, the code N ~ is obtained.

The determination of the medium pressure is carried out by calculating the pressure Np by the microcontroller 8, for example, by the formula

where a0 ... a9 are the coefficients of a polynomial describing the inverse static characteristic of a particular sensor;

Nt is the sensor temperature code obtained using temperature sensor 3.

The polynomial coefficients are calculated at the manufacturing plant as follows.

The device is placed in a heat chamber, where the maximum temperature t1 is set at which the device should work. The pressure is generated using a high-precision pressure regulator, on which three values are set in turn (minimum p1, average p2 and maximum p3 of the range of variation of the measured pressure). In this case, the output codes Nr1 and N ~ 1, Nr2 and N ~ 2, Nr3 and N ~ 3 and Nt1 are recorded. In the heat chamber, the temperature of normal conditions t2 is set. Using the pressure adjuster, four values are set in turn (minimum p4, two middle p5 and p6 and maximum p7 of the measured pressure range). In this case, the output codes No. 4 and N ~ 4, No. 5 and N-5, Nr6 and N ~ 6, Nr7 and N ~ 7 and Nt2 are recorded.

The temperature chamber sets the minimum temperature t3 at which the device should work. Using the pressure adjuster, three values are set in turn (minimum p8, average p9 and maximum p10 of the range of variation of the measured pressure). In this case, the output codes Nr8 and N ~ 8, Nr9 and N ~ 9, Nr10 and N ~ 10 and Nt3 are recorded. The coefficients of the polynomial a0 ... a9 are found from the solution of the system of equations:

The calculated coefficients a0 ... a9 are recorded in the data memory of the microcontroller 8.

The diagnostic function F is calculated in the microcontroller 8, for example, according to the following formula

The coefficients of the polynomial k0 ... k9 are found from the solution of the system of equations:

where Fn is the nominal value of the diagnostic function.

The calculated coefficients k0 ... k9 are recorded in the data memory of the microcontroller 8.

The diagnostic function F is affected only by a change in the pressure sensor parameters over time and is not affected by a change in the temperature of the sensor and the measured pressure. Deviation of the diagnostic function from the nominal value shows the occurring changes in the sensor characteristic from time to time, and by the magnitude of the deviation, it is possible to judge the change in the pressure measurement error.

Claims (2)

1. The method of measuring pressure, which consists in placing the pressure sensor in the test medium, placing the temperature sensor on the pressure sensor, registering the output signals of the pressure sensor and the temperature sensor, determining from these signals the pressure of the medium, characterized in that they form mechanical vibrations with frequency , greater than the possible oscillation frequency of the working pressure of the medium, an alternating signal with the frequency of the specified mechanical vibrations is isolated from the output signal of the pressure sensor, amplify, rectifying This signal is recorded and recorded, the diagnostic function is determined by this signal and the output signals of the sensor and temperature sensor, by the deviation of which from the nominal value the error of pressure measurement is judged. 2. A pressure measuring device comprising a pressure sensor, a temperature sensor, a two-channel analog-to-digital converter, a microcontroller, the output of a pressure sensor is connected to the first input of an analog-to-digital converter, the outputs of the digital interface of the analog-to-digital converter and the output of the temperature sensor are connected to the first terminals of the microcontroller, characterized in that a piezoelectric element is introduced, located in the medium under study near the pressure sensor, a bandpass filter, an amplifier and a rectifier, a piezo input an electric element is connected to the second output of the microcontroller, the output of the pressure sensor is additionally connected to the input of the bandpass filter, the output of which is connected in series with an amplifier, a rectifier, and a second input of an analog-to-digital converter.