RU2473919C1 - Device to convert resistance variation into voltage - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: in the device outputs of a current source and inputs of a differential amplifier are alternately connected in parallel to a strain gauge and a resistor via a switch, the output of the differential amplifier is connected with the input of the subtraction circuit, and the output of the subtraction circuit forms a device output. The measurement process includes four strokes. In the first stroke the outputs of the current source and inputs of the differential amplifier are connected to the strain gauge, in the second stroke - to the resistor. The output voltage of the first stroke is memorised in the subtraction circuit, and in the second stroke from the output voltage of the differential amplifier, the result of the first stroke is subtracted. Operation of the device in the third and fourth strokes repeats operation in the first two. The measurement result is a difference of output signals of the subtraction circuit in the fourth and second strokes, at the same time non-information components of the signal are compensated, effect of external noise is reduced to the difference of their increments, which makes it possible to place the resistor outside the zone of strain gauge location.

EFFECT: increased noise immunity of a device.

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Description

The invention relates to measuring equipment and can be used in the aviation industry, mechanical engineering, construction, etc. to study the strength of structures using single strain gages without the use of compensation strain gages.

Converters of resistance to voltage conversion are known with a single strain gauge connected in a three-wire circuit to one of the bridge arms, a power source is connected to the supply diagonal of the bridge, the output signal is taken from the output diagonal of the bridge (M.L.Daychik, N.I. Prigorovsky, G.Kh. Khurshudov, Methods and means of full-scale tensometry: A Handbook of the Basics of Designing Machines - Moscow: Mashinostroenie, 1989, p. 51, Fig. 6). The use of a three-wire inclusion of a strain gauge with equal resistance of the wires of the communication line in the bridge eliminates the influence of the initial resistances of the wires, but there remain errors from the difference in their resistances, which is most affected when working in a wide range of changes in the ambient temperature. In addition, such converters are unprotected from external interference due to the asymmetry of the strain gauge switching circuit.

There are various schemes of converters with a strain gauge connected in a three-wire circuit, which solves the problem of reducing the error from the influence of the resistance of the wires of the communication line, correcting the error from nonlinearity, subtracting a constant voltage value corresponding to the initial voltage value on the strain gauge, etc., but is not eliminated error from the influence of external noise on the measurement result. (Gutnikov BC Integrated electronics in measuring devices. - 2nd ed., revised and additional - L .: Energoato Mizdat, Leningrad Department, 1988 .-- p. 76, fig. 2.11).

Known converters of resistance to voltage with a single strain gauge connected in a four-wire circuit, in which a more complete correction of errors caused by the active resistance of the wires of the connecting line is achieved. The best performance is ensured when the strain gauge is powered by a current source. (Gutnikov B.C. Integrated Electronics in Measuring Devices. -2nd ed., Revised and additional - L .: Energoatomizdat. Leningradskoe Otdel, 1988. - pp. 78-80, Fig. 2.12, 2.13). When using two identical current sources (or one weighted one) and a reference resistor, the initial value of the voltage on the strain gauge is compensated, but the non-informative components of the signal, including the error from external interference, are not compensated.

Closest to the proposed invention is a device for converting a change in resistance to voltage, described in patent 2366966 G01R 27/02/2006, the Device contains a strain gauge, a resistor and a current source connected in series, two differential amplifiers and a switch, while the inputs of one differential amplifier through normally closed switch contacts are connected in parallel to the strain gauge and through normally open contacts in parallel to the resistor, and the inputs of the second differential amplifier dklyucheny through normally closed contacts in parallel across the resistor and the normally open - parallel to the strain gauges, the outputs of differential amplifiers are output devices.

In the absence of external interference, the device does not contain uninformative components and provides high measurement accuracy with changing ambient temperature

The disadvantage of this device is the low noise immunity, which significantly limits the area of the strain gauge and resistor.

With an additive mixture of the useful signal and interference, the interference voltage at the device output in the first measurement step:

Uout ₁ = Ku ₁ · Up _{1 -} Up ₂ · Up ₂ , where Ku ₁ and Up ₂ are the amplification factors of the amplifiers, Up ₁ and Up ₂ are the interference voltage at the input of the first and second amplifiers.

In the second measure step:

Uout ₂ = Ku ₁ · (U after ₂ + ΔU after ₂ ) -U ₂ · (Up after ₁ -ΔU after ₁ ),

where ΔUпом ₁ and ΔUпом ₂ - the increment of the interference voltage in the second measurement step.

As a result of two measures;

Uout ₁ -Uout ₂ = (Ku ₁ + Ku ₂ ) · (Up _1- Up ₂ ) + Ku ₂ · Δ Up ₁ -Ku ₁ Δ Up ₂ .

When Ku ₁ and Ku ₂ = Ku, which is almost always true:

Uout ₁ -Uout ₂ = 2 · Ku · (Uin ₁ -Unom ₂ ) + Ku · (ΔUnom ₁ -ΔUnom ₂ )

The interference voltage at the device output is absent only if the level of interference voltages at the inputs of differential amplifiers is equal. In the absence of interference at the input of one of the differential amplifiers, at the output of the device there is a two-time-amplified interference at the input of the second differential amplifier. Therefore, it is necessary to place the strain gauge and resistor in close proximity and to ensure the identity of the parameters of the connecting lines.

The technical result of the invention is to increase the noise immunity of the device.

The technical result is achieved by the fact that in the device for converting resistance to voltage, containing a strain gauge, a resistor, a differential amplifier and a switch, a bipolar rectangular current source and a subtraction circuit are introduced, while the outputs of the current source through normally closed switch contacts are connected in parallel with the strain gauge and through normally open - parallel to the resistor, the inputs of the differential amplifier are connected through normally closed contacts in parallel to the strain gauge yell and through normally open - parallel to the resistor and the differential amplifier output is connected to the input of the subtractor, the subtractor circuit forms the output of the output device.

Figure 1 shows a block diagram of a device for converting changes in resistance to voltage. The device contains a strain gauge Rtr, resistor Ro, a bipolar rectangular current source 1, a differential amplifier 3, the outputs of the current source and the inputs of the differential amplifier are connected in parallel with Rtr and Ro through a switch 4, the output of the differential amplifier is connected to the input of the subtraction circuit 2, the output of the subtraction circuit is an output transducer.

The work of the proposed device

With one state of switch 4 (contacts K1 ÷ K4 closed, K5 ÷ K8 open), the inputs of the differential amplifier 3 and the outputs of the current source 1 are connected in parallel Rtr. In the second state (contacts K5 ÷ K8 closed, K1 ÷ K4 open), the inputs of the differential amplifier 3 and the outputs of the current source 1 are connected in parallel Ro.

The measurement process consists of four measures. The first two cycles are carried out with a positive value of the current source, the third and fourth cycles - with a negative. In this case, the voltages at Rtp and Ro change their sign to the opposite, and the voltage of the low-frequency noise does not depend on the magnitude of the current and its polarity and does not change its sign.

During the first cycle, contacts K1 ÷ K4 are closed, and contacts K5-K8 are open. In this case, the voltage at the output of amplifier 3 is determined as;

Uout ₁ = Ky · I · Rtp + Ky · Upom ₁ + U ₀₃ , where I is the current of the current source 1, Ku is the gain of the differential amplifier, Upom ₁ is the interference voltage at the amplifier input in the first cycle, U ₀₃ is the proper zero offset amplifier 3.

At the end of the first cycle, the output voltage Uout _{1 is} stored by the subtraction circuit 2.

In the second cycle, the contacts K5 ÷ K8 are closed, and the contacts K1 ÷ K4 are open. The voltage at the output of the amplifier:

Uout ₂ = Ky · I · R0 + Ky · Up after ₂ + U ₀₃ ,

where Uпом ₂ is the interference voltage at the input of amplifier 3 in the second cycle. The output voltage of the subtraction circuit in the second cycle:

Ucx ₂ = Uout ₂ -Uout ₁ = Ky · I · (R ₀ -Rtp) + Ky · (Up ₂ + Up ₁ ) + U ₀₂ ,

where U ₀₂ is the zero bias voltage of the subtraction circuit 2.

The measurement process in steps 3 and 4 is carried out with a negative current value I and is similar to the work in steps 1 and 2.

The voltage at the output of the amplifier in the third cycle:

Uout ₃ = -Ku · I · (Rtr + ΔRtr) + Ky · (Un ₁ + ΔUn ₁ ) + U ₀₃ ,

where ΔUpoom ₁ is the increment of the interference voltage for the second and third measurement cycles, ΔRtr is the increment of the resistance of the strain gauge from the load for the second and third cycles.

At the end of the third cycle, the output voltage Uout _{3 is} stored by a subtraction circuit.

The voltage at the output of the amplifier in the fourth cycle:

Uout ₄ = -Ky · I · R0 + Ky · (Usp ₂ + ΔUp ₂ ) + U ₀₃ ,

where ΔUпом ₂ is the increment of the interference voltage Uпом ₂ for the third and fourth measurement steps.

The output voltage of the subtraction circuit in the fourth cycle:

Ucx ₄ = Uout ₄ -Uout ₃ = Ku · I · ΔRtr-Ky · I · (R0-Rtr) + Ky · (Un ₂ -Un ₁ ) + Ky · (ΔUn ₂ -ΔUn ₁ ).

Difference of values

Ucx ₄ -Ucx ₂ = Ku · I · ΔRtr-2 Ky · I · (R0-Rtp) + Ky · (ΔUn ₂ -ΔUn ₁ ) is the resulting transformation formula. If the resistance of the strain gauge and the resistor Rtp and R ₀ .

Ucx ₄ -Ucx ₂ = Ky · I · ΔRtp + Ky · (ΔU for ₂ -ΔU for ₁ ).

The output signal, in addition to the informative component, contains only the difference in the increments of the interference voltages over two measurement steps.

Subtraction of signals (Uout ₂ -Uout ₁ ) and (Uout ₄ -Uout ₃ ) was carried out in analog form. Subtraction of signals (Ucx ₄ -Uxx ₂ ) can be carried out after appropriate amplification in analog form or after analog-to-digital conversion in digital.

The measurement error from the non-informative component (ΔU by ₂ -ΔU by ₁ ) is negligible, since the interference, as a rule, is a low-frequency process with a period of thousands and tens of thousands of microseconds, and two measurement steps are only tens of microseconds.

Thus, the proposed device in comparison with the prototype provides a much greater degree of noise immunity of the measurement, and the resistor can be located not only in the zone of the strain gauge, but also in any other place, including and in the equipment. In this case, when calculating the strain, a correction is made for the temperature characteristic of the strain gauge.

The present invention will be used to create on-board multi-channel strain gauge equipment with a single strain gauge to study the strength characteristics of structural elements of aircraft in flight.

Claims (1)

A device for converting a change in resistance into voltage, containing a strain gauge, a resistor, a bipolar rectangular current source, a switch and a differential amplifier, characterized in that a subtraction circuit is introduced into it, while the outputs of the current source through normally closed switch contacts are connected in parallel with the strain gauge and through normally open parallel to the resistor, the inputs of the differential amplifier are connected through normally closed contacts parallel to the strain gauge and es normally open - parallel to the resistor and the differential amplifier output is connected to the input of the subtractor, the subtractor circuit forms the output of the output device.