RU123537U1 - ACTIVE RESISTANCE DEVICE - Google Patents

Abstract

A device for measuring active resistance, containing a clock pulse generator, a first counter, an indicator, a reference voltage source, first and second switches, while the first terminal of the capacitor is connected to the first input of the comparator, the second terminal is connected to the first terminal of the measured resistance, the second terminal of the measured resistance connected to the first terminal of the second switch, characterized in that the reference resistor is connected to the first terminal of the first switch, the capacitor and the input of the operational amplifier, the first input of the control device is connected to the output of the comparison device, the second input of the control device is connected to the output of the second counter, the output of the control device is connected with the first input of the first counter and the second outputs of the first and second keys, the output of the clock pulse is connected to the second input of the first counter and to the input of the second counter, the output of the reference voltage source is connected to the input of the voltage inverter and the input of the scale converter the output of the voltage inverter is connected to the third output of the first key, the output of the scale converter is connected to the third output of the second key, the output of the first counter is connected to the input of the decoder, the output of the decoder is connected to the input of the indicator, the output of the operational amplifier is connected to the first output of the capacitor and the first input of the comparison device ...

Description

The utility model relates to the field of electrical engineering, in particular to automated control systems, can be used as a measuring device in various fields of science and technology.

A device for measuring active resistance by converting it into a pulse frequency [SU 1327011 A1, IPC 4 G01R 27/00, publ. 07/30/1987], containing a current source, the first and second terminals of which are connected to the first terminals of the first and second reference resistors, respectively. The second outputs of the reference resistors are connected respectively to the first and second inputs of the device, an integrator whose output is connected to the first input of the comparator, the output of which is the output of the device. The first and second inputs of the first switch are connected respectively to the first and second terminals of the current source, and the output is connected to the second input of the comparator, the output of which is connected to the control inputs of the first, second, third and fourth switches, the first input of the second switch is connected to the first input of the third switch and through the first connecting wire - with the first input of the device, the second input - with the second input of the fourth switch and through the fourth connecting wire with the second input of the device. The first input of the fourth switch through the second connecting wire is connected to the first input of the device, and the second input of the third switch through the third connecting wire to the second input of the device. The output of the second switch is connected to the input of the integrator. The output of the third and fourth switches are connected respectively to the output and the first input of the differential amplifier, the second input of which is connected to a common point.

The disadvantages of this device are the long measurement time of the resistance of the order of tera (from several seconds) and the capacitance of an exemplary measuring capacitor, which is comparable with the installation capacity.

A device for measuring large resistances is known [Electrical measurements: Textbook for high schools / Baida LI, Dobrotvorsky NS, Dushin EM and etc.; Ed. A.V. Fremke and E.M. Dushina. - 5th ed., Revised. And add. - L .: Energy. Leningra. Department, 1980, p.146-147], which contains a reference voltage source, the first output of which is connected to the first output of the voltmeter, the first output of the capacitor and the first output of the ballistic galvanometer. The second terminal of the reference voltage source is connected to the second terminal of the voltmeter and to the first terminal of the measured resistance. The first terminal of the switch is connected to the second terminal of the measured resistance. The second terminal of the switch is connected to the second terminal of the ballistic galvanometer, and the third is connected to the second terminal of the capacitor.

The disadvantage of this device is the long measurement time due to the absence of automation elements in the circuit.

A device for measuring resistance is known [Automatic measurements and instruments (analog and digital) / P.P. Ornatsky. - 5th ed., Revised. And add. - K .: Vishka school. Head Publishing House, 1986, p.377-378], selected as a prototype, containing a capacitor, the first output of which is connected to the first input of the comparison device and the first output of the first key. The second terminal of the capacitor is connected to the first terminal of the measured resistance. The second terminal of the measured resistance is connected to the second terminal of the first key. The third output of the first key is connected to the output of the voltage reference source. The output of the quantizing pulse generator is connected to the first output of the second key. The fourth output of the second key is connected to the input of the counter, the output of which is connected to the input of the indicator.

The disadvantage of this device is the dependence of the measurement time on the value of the measured resistance and capacitance of the capacitor: with an increase in the value of the measured resistance and / or capacitance of the capacitor, the measurement time increases.

The objective of the utility model is to create a device for measuring active resistance, which allows to reduce the time of measuring large resistances (of the order of terahm).

A device for measuring active resistance, containing a clock generator, a first counter, an indicator, a reference voltage source, first and second keys, the first output of the capacitor connected to the first input of the comparison device, the second output connected to the first output of the measured resistance, the second output of the measured resistance connected to the first output of the second key.

According to a utility model, an exemplary resistor is connected to the first output of the first key, a capacitor and an input of an operational amplifier, the first input of the control device is connected to the output of the comparison device, the second input of the control device is connected to the output of the second counter, the output of the control device is connected to the first input of the first counter and second outputs the first and second keys, the output of the clock generator is connected to the second input of the first counter and to the input of the second counter, the output of the reference voltage source I am connected to the input of the voltage inverter and the input of the scale converter, the output of the voltage inverter is connected to the third output of the first key, the output of the scale converter is connected to the third output of the second key, the output of the first counter is connected to the input of the decoder, the output of the decoder is connected to the input of the indicator, the output of the operational amplifier is connected with the first output of the capacitor and the first input of the comparison device.

The proposed device allows you to record the time of the first integration cycle, which reduces the measurement time.

Figure 1 shows a block diagram of a device for measuring active resistance.

The device for measuring the active resistance contains a reference voltage source 1 (ION), to which a voltage inverter 2 (IN), a first switch 3 (K1), a reference resistor 4, an operational amplifier 5 (OS), a comparison device 6 (US) are connected in series, control device 7 (UE), the first counter 8 (SCh1), a decoder 9 (L), indicator 10 (Indus). A capacitor 11 is included in the feedback circuit of the operational amplifier 5 (op-amp) 11. A scale converter 12 (MP), a second switch 13 (K2), a measured resistance 14, and an operational amplifier 5 (op-amp) are connected in series with a reference voltage source 1 (ION).

To the clock pulse generator 15 (GTI), a second counter 16 (Сч2) and a control device 7 (УУ) are connected in series. The output of the clock generator 15 (GTI) is connected to the second input of the first counter 8 (SCh1). The second output of the control device 7 (UE) is connected to the third terminals of the first 3 (K1) and second 13 (K2) keys.

The device can be implemented using the following elements: reference voltage source 1 (ION), voltage inverter 2 (IN), first 3 (K1) and second 13 (K2) keys, operational amplifier 5 (op amp), comparison device 6 (CSS) , a control device 7 (УУ), the first 9 (Сч1) and second 16 (Сч2) counters, a decoder 9 (Дш), a clock generator 15 (GTI) of Analog Devices; indicator 11 (Indus) and scale converter 12 (MP) of VISHAY company.

The proposed device operates as follows. In the first integration step, the first switch 3 (K1) is open and the second switch 13 (K2) is closed. From the output of the reference voltage source 1 (ION), the reference voltage U _{0 is} supplied to the input of the scale converter 12 (MP), which changes the value of the reference voltage to predefined number of times. The signal from the output of the scale Converter 12 (MP) through the measured resistance 14 is fed to the input of an operational amplifier 5 (OA), the capacitor 11 is included in the feedback circuit thereof. The integration time t ₁ (first cycle) is fixed using a control device 7 (UE), the second counter 16 (SCh2) and the clock generator 15 (GTI). The voltage at the output of the operational amplifier 5 (op-amp), in the feedback circuit of which a capacitor 11 is connected, at the end of the first integration cycle is expressed by the formula [Application of operational amplifiers and linear ICs: Per. from English - M .: Mir, 1985, p.127]:

where U _I is the voltage at the output of the operational amplifier 5 (OS) at the end of the first integration cycle;

τ ₁ is the integration time constant of the integrator formed by the operational amplifier 5 (op amp), the feedback circuit of which includes a capacitor 11 and a measured resistance 14, in the first integration cycle;

t ₁ is the integration time of the first measure;

U _MP - voltage from the output of the scale Converter 12 (MP);

R _x is the measured resistance 14;

C is the capacitance of the capacitor 11;

U ₀ - voltage from the output of the reference voltage source 1 (ION);

k is the conversion coefficient of the scale Converter 12 (MP).

After the end of the first cycle, the control unit 7 (CU) starts the first counter 8 (C1) and at the same time switches the keys to the position the first key 3 (K1) is closed, the second key 13 (K2) is open. From this moment, the second integration cycle begins. From the output of the reference voltage source 1 (ION), the reference voltage U _{0 is} supplied to the input of the voltage inverter 2 (IN), which inverts the voltage (reverses the voltage polarity). The signal from the output of the voltage inverter 2 (IN) through the reference resistor 4 is fed to the input of the operational amplifier 5 (op-amp), the capacitor 11 is connected to the feedback circuit thereof. The voltage at the output of the operational amplifier 5 (op-amp) at the end of the second integration cycle is expressed by the formula [Application operational amplifiers and linear ICs: Per. from English - M .: Mir, 1985, p.127]:

where U _II is the voltage at the output of the operational amplifier 5 (OS) at the end of the second integration cycle;

where τ ₂ is the integration time constant of the integrator formed by the operational amplifier 5 (op amp), the feedback circuit of which includes a capacitor 11 and an exemplary resistor 4, in the second integration cycle;

t _x is the integration time of the second clock;

U _And - voltage from the output of the voltage inverter 2 (IN);

R ₀ - reference resistor 4.

Based on the fact that U _I = U _II (since at the beginning of the second step the voltage at the output of the operational amplifier 5 (OS) is equal to the voltage at the output of the operational amplifier 5 (OS) at the end of the first step), we equate expressions (1) and ( 2):

From the expression (3), the dependence of the time of the second integration cycle on the value of the measured resistance 14:

Expression (4) shows that in this case an inverse dependence of the time of the second cycle on the value of the measured resistance is achieved. For time t _{x, the} first counter 8 (SCh1) counts the number of pulses that come from the output of the clock pulse generator 15 (GTI):

N = f _GI · t _x ,

where N is the number of pulses calculated by the first counter 8 (SCh2) during the second cycle t _x ,

f _GI is the frequency of the clock generator 15 (GTI).

The signal from the output of the operational amplifier 5 (OS) is fed to the input of a comparison device 6 (US), where it is compared with a previously set signal (in this case, with a zero voltage level). The second integration cycle lasts until the signal about the equality of the compared signals is received at the input of the control device 7 (CI) from the output of the comparison device 6 (CI), at the same time, a signal is input from the output of the control device 7 (CI) to the input of the first counter 8 (Sch1) about the termination of the count, after which the information from the output of the first counter 9 (Sch1) is fed to the input of the decoder 10 (L), where it is converted into the necessary code, which is fed to the input of the indicator, with the help of which the measured value ivnogo resistance 10 (Ind).

Claims (1)

A device for measuring active resistance, containing a clock generator, a first counter, an indicator, a reference voltage source, first and second keys, the first output of the capacitor connected to the first input of the comparison device, the second output connected to the first output of the measured resistance, the second output of the measured resistance connected to the first output of the second key, characterized in that the model resistor is connected to the first output of the first key, a capacitor and the input of the operational amplifier, the first in One control device is connected to the output of the comparison device, the second input of the control device is connected to the output of the second counter, the output of the control device is connected to the first input of the first counter and second outputs of the first and second keys, the output of the clock generator is connected to the second input of the first counter and to the input of the second counter, the output of the reference voltage source is connected to the input of the voltage inverter and the input of the scale converter, the output of the voltage inverter is connected to the third output of the first yucha, scale transducer output is connected to the third terminal of the second switch, the first counter output is connected to the input of the decoder, the decoder output is connected to an input of an indicator of the operational amplifier output is connected to a first terminal of the capacitor and the first input of the comparator.