RU2400711C1 - Strain-measuring transducer - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: strain-measuring transducer has a tensoresistor bridge dc voltage power supply with variable polarity, a reference voltage source, a calibration signal conditioner and a system main line command decoder. The strain-measuring transducer also has a sigma-delta averaging analogue-to-digital converter which has a switch for selecting the operation mode of the converter, a device for sampling and storing the input signal, a transducer with charge compensation, a digital low-pass filter, a data register and a control register. Said measurement units are connected in a given circuit.

EFFECT: wider frequency range of measured signals, shorter time and higher measurement accuracy, simple design of the transducer.

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Description

The invention relates to the field of measuring equipment and industrial electronics and is used to measure strains, forces, pressures and other physical parameters using strain gauge sensors assembled according to a bridge circuit.

Known analog measuring transducers designed to normalize the output signals of primary transducers with strain gauges connected by a bridge circuit (see BCVolobuev, V.P. Strashnov, E.S. Suschevich, L.F. Slepchenko, A.V.Selitsky. Measuring transducers for strain gauge type Sh74. Instruments and control systems, 1985, No. 9, p.25).

The strain gauge bridge is powered by a five-wire circuit that reduces the influence of wire resistances on the measuring characteristics of the converter. The balanced output of the strain gage with the unbalanced input of the DC amplifier DCT is matched using a block consisting of a series-connected modulator M and a demodulator DM. UPT contains a preliminary amplifier U and a device for galvanic separation of UGR. The preamplifier is built on a two-channel circuit. The channel for amplifying direct current U1 is made according to the M-DM scheme, and the channel for alternating current U2 is made with direct connections. The output signals of the channels U1 and U2 are fed to the input of the UGR, consisting of a transformer unit for signal separation. In the output stage of the UGR, the signals of the DC and AC channels are summed and amplified to a level of 10 V. The converter contains an active low-pass filter of the low-pass filter on the operational amplifier to attenuate the noise level. The passband of the low-pass filter is controlled by changing the RC elements using a mechanical switch. The converter also contains a manual strain gage balancing device with an unbalance indicator.

The disadvantages of the known measuring transducer are inherent in its complex architecture with M-DM circuits, manual control of the operating modes and balancing of the strain gage, a limited measurement range, insufficient accuracy, and the absence of an analog signal to digital code converter.

The closest analogue of the present invention, adopted as a prototype, is an analog-to-digital measuring transducer of sensor signals, intended for use as part of the main-modular measuring circuits (Blockin-Mechtalin Yu.K. Measuring transducer of sensor signals for main-modular systems. Measuring technique, 1997, No. 11, p. 14). This converter contains: a power source for sensors with a constant voltage with a switchable polarity, a differential measuring amplifier with a programmable gain, integrating an analog-to-digital converter, consisting of a voltage to frequency converter with a reference voltage source and a frequency converter in a code with programmable measurement (integration) time, shaper of a calibration signal, switch for selecting an operating mode, a scale offset circuit, a control circuit for communication lines with strain gauge, galvanic separation of the analog part from the digital, the decoder of the system trunk commands.

The essential features that coincide with the essential features of the proposed technical solution are: the presence of a power supply of the sensor strain gauge bridge with a constant voltage with a switchable polarity, a reference reference voltage source, a calibration signal shaper, a system line command decoder.

The disadvantages of the prototype include: a limited frequency range of the measured signals, a significant measurement time (integration) of the signal to obtain the necessary measurement accuracy, the complexity of the architecture, including a large number of discrete elements and nodes that perform the basic conversion functions.

The technical result of the invention is to expand the frequency range of the measured signals, reduce time and improve measurement accuracy, simplify the architecture of the Converter.

The technical result is achieved by the fact that an analog-to-digital averaging sigma-delta converter, including a mode selection switch, is introduced into the strain gauge measuring transducer containing a constant voltage voltage source with a switched polarity, a reference voltage reference source, a calibration signal generator and a decoder of system line commands operation of the converter, a device for sampling and storing the input signal, a converter with balancing the charge a, a digital low-pass filter, a data register and a control register, while the first analog input of the switch is connected to the output of the measuring diagonal of the strain gage, the second analog input of the switch is connected to the input of the calibration signal generator, the input of which is connected to the power diagonal of the strain gage, the output of the switch is connected to the input devices for sampling and storing the input signal, the output of which is connected to the input of the Converter with balancing the charge, the output of which is connected to the input of a digital low-pass filter a cell whose output is connected to the input of the data register, the output of which is connected to the input of the system line command decoder, the output of the reference reference voltage source is connected to the voltage reference of the converter with charge balancing and the analog input of the strain bridge power supply, the outputs of the control register are connected to the control inputs of the selection switch operating mode of the converter, the device for sampling and storing the input signal, the converter with charge balancing and the digital filter of the lower parts one and the inputs of the control register and the digital input tenzomosta power source switchable polarity decoder connected to the output command system backbone.

Figure 1 shows the structural diagram of the proposed strain gauge measuring transducer. Figure 2 shows the algorithm of the Converter.

The proposed strain gauge measuring transducer contains: a DC voltage strain gauge bridge power supply with switched polarity 1, an analog-to-digital sigma-delta averaging converter 2, a reference reference voltage source 3, a calibration signal shaper 4, a system line command decoder 5. An analog-digital sigma the delta converter 2 includes: a switch for selecting the operating mode of the converter 6, a device for sampling and storing the input signal 7, the converter with the equations by charge cancellation 8, digital low-pass filter 9, data register 10 and control register 11.

The proposed strain gauge measuring transducer operates as follows. The voltage of the reference reference source 3 (2.5 V) required for the operation of the converter 2 is supplied to the input of the reference voltage of the IN REF converter. At the same time, the reference voltage of the source 3 is supplied to the analog input of the power source 1 to generate the supply voltage of the strain bridge U (10 V).

Strain bridge is powered by a four-wire circuit with 100% voltage feedback in order to maintain voltage stability at the vertices of the strain bridge power diagonal.

The output voltage of the strain bridge (ΔU) in the range of -2.5 ... 0 ... + 2.5 V is supplied to the analog input of switch 6 IN1 of converter 2 and is measured.

The voltage supply of the strain gauge bridge (U) from the feedback lines is supplied to the shaper of the calibration signal 4. From the output of the shaper, the calibration signal U _k goes to the analog input IN2 of the switch 6 of the converter 2 and is measured.

The control of the converter 2, the power supply of the strain gage 1 and the transfer of measurement data is carried out according to the commands from the computer, coming through the system line and the command decoder 5 to the control register 11. First, the configuration of the converter 2 is established.

The configuration of converter 2 includes: selection of the type of converter register (control or data register), operation mode (measurement or calibration), gain (from 1 to 128), digital filter notch frequency (from 10 Hz to 1000 Hz), converter channel number ( IN1 or IN2), write or read data mode. Writing configuration information and reading the output data is carried out through the bidirectional serial port of the converter 2.

During the conversion, the input signal of the selected channel is continuously modulated by the sampling and storage device 7, amplified and converted into a series of pulses in the converter with charge balancing 8. The pulse sequence is processed by a digital filter 9.

The speed of data change in the output register 10 is determined by the notch frequency of the digital filter - the first dip of the spectral characteristic, which is described by the law (sinx / x) ³ - parabolic spectral window. The notch points are repeated at multiple frequencies at which the filter produces the greatest signal attenuation. So, for example, at a frequency of 50 Hz and 60 Hz, attenuation to 100 dB is provided.

The permissible sample rate of the conversion results f _s is equal to the first notch frequency of the digital filter. The output data is read periodically with a speed that should not exceed the speed of updating (changing) data.

Since digital filtering is carried out after converting the analog-code, it eliminates the noise introduced by the conversion process.

When the input signal of the converter is changed in steps, for example, when the polarity of the voltage supply of the strain gauge bridge is switched, the time for establishing the digital filter is t _y = 4 · 1 / f _n , where f _n is the frequency of the 1st dip of the frequency response of the selected filter. So, at f _n = 10 Hz, t _y = 0.4 s.

Generating the voltage of the power supply 1 of the strain gage U and the reference voltage for operation of the converter 2 from a common reference voltage source 3, four-wire connection of the strain gage to the power supply 1 with 100% voltage feedback, the use of an analog-to-digital averaging sigma-delta converter with programmable gain and the frequency of the notch of the digital filter, the determination of the average values of the measurement results at different polarity of the voltage supply of the strain bridge, using cal transducer calibration improve measurement accuracy by reducing errors of the additive and multiplicative effect of electrical interference, change the conversion factor and the offset measuring channel zero, a thermoelectric measuring paths and other influencing factors.

The algorithm of the proposed measuring transducer is as follows (figure 2).

First, the configuration information from the computer is written to the register of the command decoder 5:

- Transmitter 2 register code (control or data);

- code of the operating mode of the converter 2 (measurement or calibration);

- code of the channel number of the converter 2 (IN1 or IN2);

- gain code (from 1 to 128);

- notch filter frequency code (from 10 Hz to 1000 Hz);

- code for writing or reading data.

Next, a cycle for transmitting configuration information from the register of the command decoder 5 to the control register 11 of the converter 2 is started. In the process of data transfer, a code is read about the beginning and end of the transmission cycle.

After the data transfer to the control register 11 of the converter 2 is completed, a signal conversion cycle is started in accordance with the established configuration of the converter. The completion of the conversion cycle is confirmed by reading the corresponding code.

After the conversion of the signal is completed, a data transfer cycle is started from the data register 10 of the converter 2 to the register of the command decoder 5. Reading of the data begins by writing to the control register of the command decoder 5 the code of the data register 10 of the converter 2. The completion of the data transfer cycle to the register of the command decoder 5 is confirmed by reading the corresponding code.

Next, the result of the conversion is read from the register of the command decoder 5 through the system bus to the computer.

The strain gauge measuring transducer is manufactured and tested as part of the main-modular weight measuring system of a wind tunnel.

The study of the transducer showed high accuracy in measuring the signals of multicomponent force transducers — aerodynamic tensile weights in the working frequency range and reducing the measurement time.

Claims (1)

A strain gauge measuring transducer comprising a constant voltage DC voltage switch with a switchable polarity, a reference reference voltage source, a calibration signal shaper and a system line command decoder, characterized in that an analog-to-digital sigma-delta averaging converter is introduced, including a mode selection switch converter, device for sampling and storing the input signal, converter with charge balancing, digital filter p low frequencies, data register and control register, wherein the first analog input of the switch is connected to the output of the measuring diagonal of the strain gage, the second analog input of the switch is connected to the output of the calibration signal shaper, the input of which is connected to the power diagonal of the strain gage, the output of the switch is connected to the input of the sampling device and storing the input signal, the output of which is connected to the input of the converter with balancing the charge, the output of which is connected to the input of a digital low-pass filter, the output of which it is connected to the input of the data register, the output of which is connected to the input of the system line command decoder, the output of the reference reference voltage source is connected to the voltage reference of the converter with charge balancing and the analog input of the strain gage power supply, the outputs of the control register are connected to the control inputs of the converter , devices for sampling and storing the input signal, a charge balancing converter and a digital low-pass filter, and the reg The control switch and the digital input of the strain gauge bridge power supply are connected to the output of the system trunk command decoder.

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