SU1113664A1 - Strain-gauge device for static measurements - Google Patents

Abstract

TENSOMETRIC DEVICE FOR STATIC MEASUREMENTS, containing a tensor63 wiring bridge, a generator, an isolating transformer with two independent input windings, one of which is connected to the measuring diagonal of the strain gauge bridge, a feedback resistor connected in parallel to the second input winding, the amplifier which has a wall with a wall piece and a piece with a wall with a wall with a wall with a wall with a wall with a wall with a wall with a wall with a wall with a wall figure. transformer, high-pass filter connected to the amplifier output, demodulator, the first input of which is connected to the filter output ver These frequencies, and the second with the generator output, and a parallel-connected load resistor and a low-pass filter capacitance, connected in series with a feedback resistor, characterized in that, in order to improve measurement accuracy, it is equipped with a frequency doubler connected between the output the generator and the power supply diagonal of the bridge, and the voltage converter are the current connected between the demodulator output and the load resistor, and the demodulator is implemented as a series of connected first analog: multiplier, ph a low pass and a second analog multiplier.

Description

The invention relates to a measuring instrument of the Chby technique, namely, to means for measuring deformations using a resistor sensor tensor. A strain gauge device containing a strain gauge bridge, a carrier frequency generator connected to a strain gauge bridge through an isolating transistor and an AC current amplifier with a demodulator output, the input of which is connected to the measuring diagonal of the strain gauge bridge, and the demodulator output are connected to a load resistor L13 are known. The disadvantage of such an embodiment of a tensometric device is the low measurement accuracy associated with a change in the characteristics of the amplifier and demodulator in time and due to a change in the ambient temperature. Closest to the proposed invention is a strain gauge device for static measurements, which contains a strain gauge bridge, a generator, an isolating transformer with two independent input windings, one of which is connected to the measuring diagonal of the strain gauge bridge, a feedback coupling resistor connected in parallel to the second input winding, an amplifier whose input is connected to the secondary winding of an isolation transformer, a high-pass filter connected to the output of the amplifier, a demodulator The first input of which is connected to the output of the high-pass filter, and the second to the output of the generator, the demodulator is connected to series-connected and parallel-connected load resistors and the capacity of the low-pass filter connected in series with the feedback resistor. The demodulator is made in the form of a synchronous key C21. The disadvantage of the strain gauge device is that the feedback depth is limited and high measurement accuracy cannot be achieved due to the wide-field system. The purpose of the invention is to improve the measurement accuracy. The goal is achieved by the fact that a strain gauge device for static measurements, containing a strain gauge bridge, a generator, an isolation transformer with two independent input windings, one of which is connected to the measuring diagonal of the strain gauge bridge, a feedback resistor connected in parallel to the second input winding, amplifier, input which is connected to the secondary winding of the isolation transformer, a high-pass filter connected to the amplifier output, a demodulator whose first input is connected en with the output of the low-pass filter, and the second with the output of the generator, and a parallel-connected load resistor and low-pass filter capacitance connected in series with the feedback resistor, equipped with a frequency doubler connected between the generator output and the diagonal of the bridge power supply, and a voltage converter - TOIC, connected between the output of the demodulator and the load resistor, and the demodulator is designed as a series-connected first analog multiplier, low-pass filter and second analog converter ozhitel. The drawing is a diagram of the strain gauge device. The strain gauge device contains a strain gauge bridge 1, a generator-, a torus 2, an isolation transformer 3 with two independent input windings 4 and 5. The winding 4 is connected. with the measuring diagonal of the strain gauge bridge 1. The resistor 6 is connected in parallel with the second input winding 5 of the isolation transformer 3. In addition, the device contains an amplifier 7, the input of which is connected to the secondary winding of the separation transformer 3, a high-pass filter 8 connected to the output amplifier 7, demodulator 9, the first input of which is connected to the output of the high-pass filter 8, and the second to the output of the generator 2, the resistor 10 of the load connected in parallel and the capacity of the low-pass filter 11, connected nnye resistor 6 in series with the feedback frequency doubler 12, which is connected between the output of the generator 2 and the diagonal of the bridge supply 1, the inverter 13, voltage-current, which is included between the output of the demodulator 9 and the resistor 10 loading. E11 Demodulator 9 BbmonHieH in the form of serially connected first analog multiplier 14, low-pass filter 15 and second analog multiplier 16. The device works as follows. Generator 2, through frequency doubler 12, provides the voltage across the diagonal of the power supply of bridge 2 at a frequency twice the higher frequency of the generator. The voltage unbalance of the strain gauge bridge 1 from its measuring diagonal is fed to the winding 4 of the isolation transformer 3. In the secondary winding of the transformer 3 a voltage is applied that is applied to the input of amplifier 7. The amplified voltage of the signal goes to the high-pass filter 8, which attenuates low-frequency noise . The signal is then demodulated by double conversion using analog multipliers. The input of the first multiplier is the voltage yt) (t) l lUexCOSe (9) oi where K is the coefficient of amplifier 7, transformer 3, high-pass filter 8; UujtW) 52bH, t-voltage on the measuring diagonal of the strain gauge bridge. The second input of the analogue transducer receives the voltage from the output of generator 2, equal to U SL t (2) where DO is the amplitude of the output voltage of the generator, yy (, is the circular frequency of the generator At the output, the analog multiplier l 14 voltage is determined by the equation: U , (t) U (t) -UrW it Cl. "(COStt, Jitfot) .... where k: K. K K (p is the transfer coefficient of the converter 1. The voltage U ((i) goes into the filter 15 of the lower frequencies, which transmits the component "(t)" K; uebv. ") s" i);: (4) itlopM /, VI V y where k ;; l dffc 2 64 s low-pass filter 15 voltage UqH (4 is fed to the input of the second analogue multiplier, at the output of which voltage arises) --Ucp "4 (i - Ur (О kj UBV (1 +. fCos 2tt) ot) - КгUav v.tUexcos 2" 0ot. (5) in accordance with equation (5) we have at the output of the second analog multiplier a constant component, i.e., proportional to the imbalance of the bridge circuit, a variable component corresponding in spectrum to the input signal, equal to KjUeyCoS 7.Uot, and proportional to the unbalance of the bridge circuit in the alternating current. The second component is used as a feedback voltage source. The voltage from the output of the second analog multiplier is fed to the input of the voltage-current converter 13, at whose output a current proportional to the input voltage is formed, without changing the spectral composition. The output current of converter 13 passes through a load resistor 10, on which a part of the constant component is separated, and through a feedback resistor 6. The variable and constant components are assigned to it. The constant component is cut off by separation transformer 3, and the variable is the component and there is a feedback voltage. In this strain gauge device, strain gauges R can be used only with resistive transducers of mechanical stresses, deformations or displacements into an electrical signal, but also inductive, capacitive or rheochord transducers. Such a performance of the strain gauge device allows to obtain a narrow bandwidth and cover all the elements, namely the amplifier, high-pass filter and demodulator, with deep negative feedback, which allows to improve the measurement accuracy, since the transmission coefficient stability of such a device the stability of the strain gauge bridge 1, the isolation transformer 3 and the feedback resistor 6, which can be easily performed with high accuracy and stability.

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Claims (1)

TENSOMETRIC DEVICE FOR STATIC MEASUREMENTS, containing a strain gauge bridge, a generator, an isolation transformer with two independent input windings, one of which is connected to the measuring diagonal of the theoresistor bridge, a feedback resistor connected in parallel with the second input winding, an amplifier whose input is connected to the secondary transformer , a high-pass filter connected to the output of the amplifier, a demodulator, the first input of which is connected to the output of the high-pass filter frequency, and the second - with the output of the generator, and a parallel-connected load resistor and a low-pass filter capacity, connected in series with a feedback resistor, characterized in that, in order to increase the accuracy of measurements, it is equipped with a frequency doubler connected between the generator output and the diagonal power supply of the bridge, and the voltage-current converter connected between the output of the demodulator and the load resistor, and the demodulator is made in the form of series-connected first analogue: multiplier, lower filter stot S ω a g and the second analog multiplier.