SU1675696A1 - Strain gauge with temperature compensation - Google Patents

Abstract

The invention relates to load measuring technology. The aim of the invention is to improve the accuracy of temperature compensation and temporal stability of the device. The stabilized voltage source 1 supplies the thermal bridge 4 and, through the thermo-dependent resistor 2, supplies the tens-bridge 3. The thermo-dependent resistor 2 serves to compensate for the temperature change of the tens-bridge. The signal is fed to the input of amplifier 5. The imbalance of the thermal bridge 4 is fed through amplifier 7 to the input of bias amplifier 5, which compensates for the temperature leaving of the amplifier zero. 1 il.

Description

ate

WITH

The present invention relates to a load measuring technique or a pressure measuring technique.

The aim of the invention is to improve the accuracy of temperature compensation and temporal stability of the device.

Diagram of the device shown in the drawing.

The device contains a source of stabilized voltage, a thermowave resistor 2, a strain gauge 3, formed by resistors R1 ... R4, a thermal bridge 4, formed by resistors R5..R9, measuring amplifier 5, jumper block 6, amplifier 7.

The device works as follows.

The stabilized voltage source 1 supplies the thermal bridge 4, and through the thermo-dependent resistor 2 - supplies the strain gauge 3. The thermal-dependent resistor 2 (R5) is used for temperature compensation of the change in the range of the strain gauge. The value of the resistor R5 depends on the temperature changes of the elastic properties of the sensing element and the resistance of the strain gauge. The resistor value is selected experimentally for each type of sensor. For example, for a sensitive element made of steel 40HNM2A and an input resistance of a strain gauge 400 Ohm R5 30 ± 1 Ohm. The imbalance of the strain gauge is fed to the inputs of the measuring amplifier 5, whose coefficient is determined by the expression

Rn + R12

Ki

Rio

ABOUT

s |

on o o o

Os

where Ki is the gain of the measuring amplifier;

R10 ... R12 are the resistance values of resistors R10 ... R12.

The output of the sensor is a voltage signal (0-10) V.

The unbalance of the thermal bridge enters the inputs of the amplifier 7, the output voltage of which is determined by the expression

Ur ± K2 (t-20),

where "2 is the proportionality coefficient, V / ° C;

t is the ambient temperature.

The output signal of amplifier 7, proportional to the temperature deviation from 20 ° C, is fed to the bias input of the measuring amplifier 5. The values of resistors R13, R14, R15 and R16 are equal to each other, and the output voltage of amplifier 5 is determined by the expression

 U -Ki ± K2 (t-20), where AU is the imbalance of the strain gauge.

The temperature sensor zero compensation is performed as follows.

At a temperature of 20 ° C, adjusting the zero of amplifiers 5 and 7 sets the zero signal at the output of the sensor. After that, the sensor heats up and, in the case of an increase in the voltage of the output signal of the sensor, the inputs of amplifier 7 are connected via jumpers 6 to the thermal bridge 4 according to the basic switching circuit. thermal bridge. In this case, instead of resistors R19n R20, resistors are installed in the device, and with their help the minimum value of amplifier 7 is set. initial state, i.e. to zero. The gain of amplifier 7 is determined by the ratio R19 / R20,

moreover, R17 / R18,. The values of resistors R19 and R20 are selected from the E192 row (GOST 10318-74), and the closest to the values obtained at the resistance stores. Depending on the position of the jumpers 6, the sensor output signal is determined by the expressions UBux AU-Ki-K2 (t -20) or willow AU-Ki + K2 (t-20),

which provides the right direction of compensation.

The strain gauge circuit does not contain additional resistors inside the strain gauge, which significantly reduces the number of

soldering points from 10 to 4 points. As a result, the aging effect of the soldering points is reduced and the temporal stability of the strain gauge is increased. In addition, the proposed technical solution compared to

the prototype allows to increase the accuracy of temperature compensation zero and reduce the additional temperature error.

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Claims (1)

Invention Formula Temperature compensated strain gauge containing series-connected stabilized source voltage, thermo-dependent resistor and temperature-measuring bridge, measuring amplifier, whose inputs are connected to the corresponding points of the diagonal of the bridge, characterized in that, in order to increase accuracy of temperature compensation and time stability of the strain gauge; thermal bridge with the second thermal-dependent resistor connected to one of the arms, jumper block and thermal bridge unbalance amplifier, the inputs of which are connected to the corresponding bridge of the thermal bridge diagonal, are inserted into the device; measuring amplifier, and the input of the thermal bridge is connected to the output of the source of stabilized voltage.