SU1732155A1 - Device for measuring linear dimensions - Google Patents

Abstract

The invention relates to mechanical engineering measurement technology and is intended for use in electronic devices for measuring linear dimensions of products. The object of the invention is to simplify the design and increase the measurement accuracy. The device comprises a stable amplitude generator 1, an inductive sensor 2, an inverting operational repeater 3 and a generator voltage 1, an inverting operational voltage amplifier AC, two rectifiers 5 and 6 of opposite voltage, an amplifier 7 voltage indicating device 8 and potentiometer 9 for bias the reading of the instrument 8. 2 sludge.

Description

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The invention relates to mechanical engineering measurement technology and can be used in devices intended to measure the deflected linear dimensions of products with the help of inductive sensors.

Various devices are known for measuring linear deviations in which inductive displacement sensors are used.

The known device comprises an inductive differential sensor connected in the form of a bridge circuit, a medium-tap transformer in one of the windings, and a stable amplitude generator and an AC voltage amplifier, a phase detector, a DC voltage amplifier, and a display device connected in series with the secondary winding of the transformer.

The disadvantages of this device are the presence of a transformer, which is laborious to manufacture, the need to pre-balance the bridge circuit with the average position of the moving link of the inductive sensor.

In the known devices, for measuring linear dimensions, a nondifferential sensor cannot be used instead of a differential sensor due to a significant difference in the connections and parameters. But the advantage is that since the differential inductive sensor signal needs to be amplified at least 200 times, to reduce the drift of the amplified sensor signal, it will be possible to amplify the signal with an ac voltage amplifier of 100 pd3, and with a constant voltage amplifier. current twice.

A device in which there is no transformer in a bridge circuit with a differential inductive sensor is known. This device contains an amplitude-phase discriminator (AFC) which replaces a transformer and a phase deyuor, and a series-connected DC amplifier and indicating device, the APD contains two differential AC voltage amplifiers with unequal gain factors for inverting and non-inverting inputs, between the outputs of which there is a circuit of

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two diodes in series in the conductive direction and two resistors, and there must be a stable amplitude generator for powering the differential sensor.

The known device permits the use of a bridgeless scheme, whereby the working section with high linearity of the conversion characteristic is expanded, the device scheme is simplified, the cost is reduced, and the measurement accuracy is increased by an order of magnitude.

But in this description it is not indicated how the bridgeless scheme will look, and its merits are indicated for the bridgeless one. If, for example, the middle sensor output is connected to ground,

0 then the circuit will be bridged and operational in the absence of a generator connection to the ground. If, however, one of the extreme terminals of the sensor is connected to ground, the circuit will be non-operable due to the fact that one of the differential amplifiers of the AFI will become non-differential, i.e. non-inverting and will amplify half the generator voltage, while the other amplifier will amplify the entire voltage of the generator with the inverting input and amplify the generator half voltage with a gain more than once with the non-inverting input. If, for example, the gain for the non-inverting input of both amplifiers is two, then the input of the UFL will be at the middle position of the moving link of the sensor

voltage equal to the magnitude of the amplitude n and the voltage of the generator.

If the differential sensor is powered by a generator through a transformer with a grounded mid point in the secondary winding, then a known device will have a bridge circuit and will be operational. In this case, AFD amplifiers will differentially amplify two signals: a generator voltage with an inverting input and a very small signal from the middle output of the sensor with a non-inverting input, i.e. AFD amplifiers will not be able to amplify the sensor signals more than 2 times. In addition, the circuit of the known device is inoperable. In the absence of a generator for powering a variable voltage sensor

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and the direct current at the output of the AFD amplifiers should be near zero. But since the non-inverting input of amplifiers to AGoD does not have a galvanic connection with the common power supply bus, the output of the amplifiers will be either all positive or all negative voltage of the power supply, i.e. the amplifiers will find with in saturation mode. To eliminate this drawback, it is necessary to connect the middle pin of the differential sensor through a resistor or choke to a common power bus.

The known device will be operable only with a bridge circuit and in the presence of a galvanic connection with a common power bus of the non-inverting input of the AFD amplifiers.

But from this it follows that this device will not have those advantages that are indicated.

The device has a significantly greater drift of the amplified signal of the differential sensor. The signal from the middle output of the sensor can be amplified by the amplifiers of the APD by a factor of 2. The circuit and serially connected passive elements in the form of two diodes and two resistors, connected between the outputs of the AFD amplifiers, will have a signal transfer ratio of about 0.5. From this it follows that for amplifying the sensor signal, for example, 200 times the gain of the UFD should be 200. If the YDUD2 integrated circuit, which has TU, is used as AFD amplifiers. The drift of the bias voltage is 50 µV / K, then when amplified by 200 times, the drift of the amplified sensor signal will be 10 mV / K due to the effect of temperature on the AFD amplifiers. In addition, in the amplified signal of the sensor there will be a 200-fold increase in the drift of the bias voltage of the diodes and the DCF itself.

Thus, the drawbacks of the device are with the bridge circuit the low measurement accuracy due to the high drift of the amplified sensor signal and the inoperability of the bridgeless circuit.

The aim of the invention is to simplify the design by employing a bridgeless scheme and improving the measurement accuracy by reducing the amplified signal drift. And I also have the ability to convert

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the same signal device of a non-differential inductive sensor with a variable air gap.

The goal is achieved by the fact that in a device containing an inductive differential linear displacement sensor, a generator of stable amplitude and frequency, two

Q opposite voltage voltage rectifier and series-connected DC voltage amplifier and indicating device, with the rectifier output connected to the input of the DC voltage amplifier, an inverting repeater and an inverting AC voltage amplifier are inserted, the repeater input is connected the output of the generator, the input of the inverting amplifier is connected to the output of the repeater and to the middle terminal of the differential inductive sensor, the extreme terminals of which are connected according to It is connected to the zero power bus and to the generator output, and the rectifier input is connected respectively to the output of the inverting repeater and the inverting amplifier.

FIG. 1 is a schematic of a device for measuring linear dimensions; FIG. 2 is a diagram of a device for measuring linear dimensions in which a non-differential inductive sensor with a variable air gap is applied.

The device contains an inductive differential sensor 1, the moving link 2 of which is associated with the measured

0 by object 3, a generator k for powering sensor 1, an inverting repeater 5 and an inverting amplifier 6, which are made on operational amplifiers, rectifiers 7 and 8 voltages

5 of the opposite sign, made according to the doubled rectified voltage scheme, the amplifier 9. DC voltage, which is made on the operational amplifier, and showing the device 10.

The generator b is connected to the output terminals of the differential sensor 1, the repeater input 5 is connected through a resistor 11 to the generator output 5 and the output to the input of the rectifier 7, the input of the amplifier 6 is connected through a resistor 12 to the middle output of sensor 1 and through a resistor 13 from the output

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repeater 5 and output with rectifier input 8.

Such a connection makes it possible to obtain a second arm of a bridge circuit, with which the voltage generator is compensated at the input of an amplifier that amplifies the sensor signal.

The input of amplifier 10 is connected via resistors 1 and 15 to the output of rectifiers 7 and 8 and through a resistor 16 to a variable resistor 17, which is intended to bias the readings of the device 10. The generator voltage should be approximately 1-8, frequency 10-15 kHz.

The resistance of resistances 1 and 15 and the transfer coefficient of rectifiers 7 and 8 must be the same. The voltage gain from the rectifier output by the amplifier 9 must be two. Rectifiers 7 and 8, made according to the rectifier voltage doubling scheme, will have a transmission coefficient of about two.

If it is necessary to amplify the signal from the middle output of the sensor by 200 times, the amplifier 6 must have a gain of 50 for the signal coming through the resistor 12. Resistor 13 must have such a resistance so that when the moving element of the sensor is in the middle position of the amplifier 6, was equal to the voltage at the output of the repeater 5. From this it follows that in this case the resistance of the resistor 13 should be greater than the resistance of the resistor.

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time.

An inductive non-differential sensor with a variable air gap (Fig. 2) consists of a ferromagnetic armored core 18 with a winding and a disk frame 19. Yoke 19 is a movable element of the sensor and is associated with the object to be measured 3.

The inductive non-differential sensor is connected to the output of the generator k through a capacitor 20, the reactance of which, to ensure a linear conversion characteristic, must be equal to the reactance of the inductive sensor with the movable frame 19 fully retracted.

With the connection point of the output winding inductance 18 and the capacitor

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20 connects the input of amplifier 6 through a resistor 12. This non-differential sensor, made on the armor core 518, has a linear conversion characteristic with a deviation of no more than 2% to an air gap of 1.2 mm. With this air gap, the magnitude of the voltage drop across the reactance of the inductive sensor will be two times greater than the voltage of the generator, and the reactance of the capacitor will be equal to the voltage of the generator.

When the air gap of the sensor is near zero, the voltage drop across the reactance of the inductive sensor will be equal to the voltage of the generator, and the reactance of the capacitor will be about zero. Since the sensitivity of such a non-differential sensor is significantly higher than that of a differential with the same power supply voltage, the gain 6 must be no more than 2. The resistance of resistor 12 in this case must be of such a value that with an average air gap in the non-differential sensor 0,6 mm voltage at the output of the amplifier 6 was equal to the voltage at the output of the repeater 5.

The proposed device works as follows.

An inductive differential sensor (Fig. 1) serves as a generator voltage divider. With the average position of the movable link 2 of the sensor, the voltage at the average output of the sensor will be 2 times less than the generator voltage. The current of this voltage is supplied through resistor 12 to the inverting input of amplifier 6, to which the voltage from the output of the repeater 5 with the opposite phase flows through resistor 13. Thus, the amplifier 6 will amplify small values of the difference between two large voltages, one of which will vary by a small amount in proportion to the displacement of the moving link of the inductive sensor.

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With the average position of the moving link of the voltage sensor at the output. Rectifiers 7 and 8 will be equal and opposite in sign and with the average position of the variable-speed slider.

The sensor 10 of the device 17 will be zero.

The displacement of the movable Even inductive sensor in one direction or another, depending on the change in the size of the object being measured, will lead to a change in the voltage at the output of the rectifier 8 and to a proportional change in the readings of the device 10.

Since the resistance of the resistors and 15 at the input of the amplifier 10 and the transfer coefficient of the rectifiers are the same, then when the moving element of the inductive sensor is in the middle position and the variable resistor 17 engine is in the middle position, the instrument 10 will not change, as in the bridge circuit of the differential sensor change in generator voltage or change in ambient temperature.

The signal drift at the output of the amplifier E will not be more than known analogs, since the amplifier E will only amplify the rectifier's drift by 2 times. If the rectifiers are made according to a different scheme, in which they will have galvanic connection with the outputs of repeater 5 and amplifier 6, then it will be necessary to connect capacitors in series with resistors 12 and 13. In this case, the gain of the amplifier 6 with direct current will be equal to one and the amplifier 10 will amplify and bias the drift of the operating amplifier bias by 2 times, the value of which at the output of the DC control will be less than in the prototype, for example, 100 times.

The advantage of the proposed device is the absence in it of laborious in the manufacture of transforming

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the torus is simpler while retaining the advantages of a bridge circuit, and it can use a non-differential inductive sensor with a variable air gap, and compared to the known one it is operational with a bridgeless circuit and has a two-fold lower drift level the amplified signal of the inductive sensor, i.e. higher measurement accuracy.

Claims (1)

Invention Formula A device for measuring linear dimensions, containing an inductive differential linear displacement sensor, a stable amplitude generator and frequencies connected in series to a constant-voltage amplifier, whose input is connected to the outputs of two opposite-voltage rectifiers, and showing a device connected by another input to a common bus , characterized in that, in order to simplify the device and improve measurement accuracy by reducing the sensor signal drift, a repeater and amplifier are introduced into it AC voltage, the outputs of which are connected to the inputs of the corresponding voltage rectifiers of opposite signs, and the inverting inputs are connected respectively to the output of the generator of stable amplitude and frequency and the output of the repeater connected to the middle terminal of the inductive differential linear displacement sensor, the outermost terminals of which are connected respectively to the output generator of stable amplitude and frequency and with a common bus. -HHfrfrH Me and. / / s AND Kfl AND: Chg g y