RU2042934C1 - Device for measuring non-electric values - Google Patents

Abstract

FIELD: instruments. SUBSTANCE: device has capacitor-based differential pressure sensor with flexible diaphragm and two pneumatic inputs, converter of sensor capacitance to electric signal, and two monitoring units. In addition device has reference capacitor, two low-pass filters, differential amplifier, voltage clipper. This results in possibility generate signal for automatic compensation of pneumatic pressure to diaphragm of sensor due to electrostatic pressure to diaphragm caused by compensating voltage. Level of this voltage depends on measured value. Error in measuring is less than 1-2% EFFECT: increased precision. 2 dwg

Description

 The invention relates to measuring technique and is intended for measuring small differences in pneumatic pressure when measuring the flow rate or velocity of the gas stream, as well as for measuring small pressure differences that occur on obstacles to the flow of gas.

A device for measuring low pressures is known, comprising a differential pressure switch with a membrane, a travel limiter, an element for setting a power control action, an indicator and an electronic converter [1]
A device is also known that converts pressure into an electrical signal containing an elastic sensor, a differential transformer, a generator, an inverter, a comparator, a trigger, and an integrating amplifier [2]
A disadvantage of the known devices is the low sensitivity when measuring small pressure drops and, as a consequence, low accuracy due to the perceptible mass of the moving elements of the sensor.

 The closest in technical essence to the proposed device is a device for measuring non-electric quantities [3] which contains a capacitive differential sensor with one common ground and two differential leads, two resistors, two elements NOT, element 2I-NOT, pulse shaper, two diodes, two the registration unit and the input bus, which through the first and second resistor is connected to the inputs of the first and second elements, respectively, NOT, the outputs of which are connected respectively to the first and second blocks reg and to the first and second inputs of the 2I-NOT element, the output of which through a pulse shaper is connected to the anodes of the first and second diodes, the cathodes of which are connected to the inputs of the first and second elements of NOT and the first and second differential outputs of the capacitive differential sensor.

 This device allows you to measure small pressure drops when using an elastic membrane in a capacitive pressure sensor. However, the nonlinearity of the elastic properties of the membrane, the varying degree of tension of the elastic membrane from sample to sample, and the change in the elasticity of the membrane of the pressure sensor during long-term operation adversely affect the accuracy of measuring small pressure drops.

 To improve accuracy when measuring small pressure drops in devices for measuring the flow rate or velocity of a gas stream, as well as when measuring the pressure drop generated by obstacles to a gas stream, into a known device containing a capacitive differential sensor with one common ground and two differential leads, two resistors , two elements NOT, element 2I-NOT, a pulse shaper, two diodes, two recording units and an input bus, which is connected through the first and second resistors to the inputs of the first of the second and second elements NOT, the outputs of which are connected respectively to the first and second recording units and to the first and second inputs of the 2I-NOT element, the output of which through a pulse shaper is connected to the anodes of the first and second diodes, the cathodes of which are connected to the inputs of the first and second elements, respectively NOT, the first differential output of the capacitive differential sensor is connected to the input of the first element NOT, a reference capacitor is introduced, the outputs of which are connected to the input of the second element NOT and to the common bus, source pressure differential with two pneumatic outputs, which are connected respectively to the first and second inputs of a capacitive differential sensor made in the form of a pressure sensor with two pneumatic inputs, two low-pass filters, a differential amplifier, a voltage limiter and a third recording unit, the outputs of the first and second elements are NOT through respectively the first and second low-pass filters are connected respectively to the first inverting and second non-inverting inputs of the differential amplifier , The output of which via a voltage limiter connected to the second terminal differential capacitive differential pressure sensor and to the input of the third recording unit.

 In FIG. 1 is a block diagram of a device for measuring non-electric quantities; figure 2 an example implementation of the device.

 A device for measuring non-electric quantities contains a capacitive differential pressure sensor 1 with plus "+" and minus "-" pneumatic inputs, with one common ground terminal "a" and two differential terminals "b" and "c", resistors 2 and 3, elements NOT 4 and 5, element 2I-NOT 6, pulse shaper 7, diodes 8 and 9, first and second recording units 10 and 11, input bus 12, two low-pass filters 13 and 14, differential amplifier 15, voltage limiter 16, third registration unit 17, a reference capacitor 18 and a differential pressure source nineteen.

 Resistors 2 and 3, the capacitance "b" of the sensor 1 and the capacitance of the reference capacitor 18 form two phase-shifting circuits that provide a time delay for the transition of the logical state 1 to state 0 at the inputs of the elements NOT 4 and 5.

 If the time delays of the phase-shifting chains are equal, the state “0” is present on the input bus 12 and in the absence of a pneumatic signal, short pulses simultaneously appear at the outputs of the elements 4 and 5, triggering the pulse shaper 7, which ensures a cyclic capacity charge-discharge process.

 The differential signal at the inputs of the differential amplifier 15 is 0 and there is no compensating voltage at the differential output "to" sensor "1".

 When the gas pressure is exerted on the membrane of the sensor 1 from the output of the pressure differential source 19, the capacitance “b” of the sensor 1 increases, the equality of the parameters of the phase-shifting chains is violated, and pulses appear on the output of the HE 5 element, the duration of which is proportional to the acting pneumatic signal.

 The constant component of the pulse sequence is extracted by a low-pass filter 14, amplified by a differential amplifier 15, and fed through a voltage limiter 16 to the differential output "to" of the sensor 1, balancing the pneumatic pressure. The value of the compensation voltage corresponds to the level of the pneumatic signal and is measured by the block 17 registration. When the voltage reaches the level of limitation in the limiter 16, the information is recorded by blocks 10 and 11.

 The device operates as follows.

 If there is a logical state 0 on the input bus 12, the capacitance “b” of the sensor 1 and the capacitance of the reference capacitor 18 are discharged. At the outputs of the elements NOT 4 and 5, as well as at the inputs of the 2I-NOT 6 element, the logical 1 state is triggered by the pulse shaper 7. The pulse from the shaper 7 through the diodes 8 and 9 “instantly” charges the capacitance “b” of the sensor 1 and the capacitance of the reference capacitor to the logical level 1. The trailing edge of the pulse at the inputs of the elements 4 and 5 is delayed in accordance with the parameters of the phase-shifting chains and when they are equal ( in the absence of gas pressure on the membrane of the sensor 1) at the outputs of elements NOT 4 and 5, the state of logical 1 appears simultaneously and the process repeats. As a result, an identical sequence of very short pulses is present at the inputs of the low-pass filters 13 and 14, and the differential signal at the input of the amplifier 15 is 0. If there is a gas flow at the output of the source 19, a pressure drop appears that acts on the elastic membrane from the side of the tank sensor 1. The capacitance "b" of the sensor 1 increases and the time constant of the phase-shifting circuit, consisting of the capacitance "b" of the sensor and resistor 2, increases.

 Since the time constant of the phase-shifting circuit, consisting of the capacitor 18 and resistor 3, does not depend on the input pneumatic signal, at the input of the element HE 5 the transition of state 1 to state 0 is ahead of the same process at the input of the element HE 4 by a time interval whose value is proportional to the pressure on the elastic membrane sensor 1. At the output of the element NOT 5 appears a sequence of pulses, the duration and constant component of which is proportional to the level of the pneumatic signal from the output of the source 19.

 The mismatch signal from the output of the element NOT 5 through the low-pass filter 14 is fed to the non-inverting input of the differential amplifier 15 and then through the voltage limiter 16 is fed to the capacitance "in" of the sensor 1 and the registration unit 17.

The voltage U on the capacitance "in" of the differential sensor 1 creates an electrostatic pressure Δ P _e.s. whose value, taking into account the proportionality coefficient K, is determined by the formula
Δ P _e.s. K ˙ U ² .

Electrostatic pressure returns the membrane to its original position with a residual error tending to 0 at a sufficiently large gain in the feedback ring. The pneumatic pressure Δ P _mon created by the differential pressure source 19, with a sufficient degree of compensation, is equal to the electrostatic pressure. Measuring the magnitude of the compensation voltage according to the readings of the registration unit 17, judge the magnitude of the pressure or flow, or gas flow rate. For a gas flow meter using a standard constriction device as a source of differential pressure, the dependence of the flow on the compensation voltage is a linear function. The use of an air pressure receiver (LDPE tube) as a source of differential pressure makes it possible to measure the speed of the incoming air flow. The dependence of the measured speed on the compensation voltage is also linear. The use of a capillary tube in gas flow meters gives a quadratic dependence of the measured gas flow on the compensation voltage.

 The voltage limiter 16 provides a limit value of the compensating voltage U "from the bottom" to the zero level to eliminate the likelihood of positive feedback in case of accidental occurrence of the reverse gas flow, the flow rate of which is measured.

 In this case, the reverse gas flow is measured by the registration unit 10.

 The limiter 16 also provides a limitation of the value of the compensating voltage "from above" at a level not exceeding the value of the electric breakdown voltage of the gap between the elastic membrane and the capacitive electrode "in" differential pressure sensor 1.

 At high levels of the measured pressure or flow rate, when the compensation voltage reaches the limit level, the measured value is judged by the sum of the readings of the recording units 11 and 17.

 The accuracy of measuring small pressure drops and, accordingly, the flow rate or gas flow rate, is determined mainly by the accuracy class of the recording unit 17 and is practically independent of changes in the elastic properties of the sensor’s elastic membrane during operation. The inventive device has the advantages inherent in compensation type devices.

 The use of an elastic electrically conductive membrane with a thickness of 3-10 μm and a mass of up to 10 mg provides the minimum energy consumption of the electrostatic field for the deformation of the membrane near the middle position and to overcome the force of gravity and allows you to implement a highly sensitive meter for small pressure drops or gas micro-flow.

 Experimental studies of a capillary micro-flowmeter of air constructed in accordance with this device showed a basic error of 1-2% and a sensitivity of no worse than 0.1 l / h.

Claims (1)

 DEVICE FOR MEASURING NON-ELECTRIC VALUES, containing a capacitive differential sensor with one common ground and two differential outputs, two resistors, two elements NOT, element 2I-NOT, pulse shaper, two diodes, two recording units and an input bus, which is through the first and second resistors connected to the inputs of the first and second elements, respectively, NOT, the outputs of which are connected respectively to the first and second blocks of registration and the first and second inputs of the element 2I-NOT, the output of which is through the shaper pulses are connected to the anodes of the first and second diodes, the cathodes of which are connected to the inputs of the first and second elements NOT, respectively, the first differential output of the capacitive differential sensor is connected to the input of the first element NOT, characterized in that the capacitive differential sensor is made in the form of a capacitive pressure sensor with two pneumatic inputs and a reference capacitor is introduced into it, the terminals of which are connected to the input of the second element NOT and to the common bus, a differential pressure source with two pneumatically the outputs that are connected to the first and second pneumatic inputs of the capacitive differential pressure sensor, two low-pass filters, a differential amplifier, a voltage limiter and a third recording unit, the outputs of the first and second elements are NOT connected through the first and second low-pass filters to the first inverting and to the second non-inverting inputs of the differential amplifier, the output of which is connected via a voltage limiter to the second differential output differential pressure sensor and to the input of the third registration unit.

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