RU152856U1 - ACTIVE RESISTANCE DEVICE - Google Patents

Abstract

The device for measuring the active resistance contains a clock generator, a counter, a reference voltage source, while the first output of the capacitor is connected to the first input of the comparison device and the output of the operational amplifier, the second output of the capacitor is connected to the first output of the measured resistance, the first output of the reference resistor 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 counter, exit the clock generator is connected to the counter input, the decoder output is connected to the indicator input, characterized in that the output of the reference voltage source is connected to the first output of the switch, the second output of which is connected to the input of the inverting amplifier, the third output of the switch is connected to the second output of the measured resistance, the output the inverting amplifier is connected to the second output of the reference resistor, the first output of the control device is connected to the input of the decoder, the second output of the control device with one with the fourth pin of the switch.

Description

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

A device for measuring active resistance [RU 145579 A1, IPC G01R 27/00, publ. 09/20/2014], containing a clock generator, first and second counters, a reference voltage source, first and second keys, the first capacitor output connected to the first input of the comparison device and the output of the operational amplifier, the second capacitor output connected to the first output of the measured resistance, the first terminal of the reference resistor and the input of the operational amplifier, the second terminal of the measured resistance is connected to the first terminal of the second key, the reference resistor is connected to the first terminal of the first key, per the output 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 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 the second counter, the output of the first counter is connected to the input of the decoder, the output of which is connected to the input of the indicator. The output of the reference voltage source is connected to the input of the inverting amplifier and the second key, the output of the inverting amplifier is connected to the third output of the first key.

The disadvantages of this device are the long measurement time of the resistance of the order of Ohms (from several seconds) and the capacity of the reference 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 terminal of which is connected to the first terminal of the voltmeter, the first terminal of the capacitor and the first terminal 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 large measurement error.

A device for measuring resistance [Automatic measurements and devices (analog and digital) / PP Ornatsky. - 5th ed., Revised. And add. - K .: Vishka school. Head Publishing House, 1986, p. 377-378], 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.

A device for measuring active resistance [RU 123537 U1, IPC G01R 27/00 (2006.01), publ. 12/27/2012], selected as a prototype, containing a clock generator, a first counter, an indicator, a voltage reference, the first and second keys. The first output of the capacitor is connected to the first input of the comparison device and the output of the operational amplifier. The second terminal of the capacitor is connected to the first terminal of the measured resistance, the first terminal of the reference resistor and the input of the operational amplifier. The second terminal of the measured resistance is connected to the first terminal of the second key. A reference resistor is connected to the first terminal of the first key. 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 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 terminal of the first switch. 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 decoder output is connected to the indicator input. The output of the operational amplifier is connected to the first output of the capacitor and the first input of the comparison device.

The disadvantage of this device is the large measurement error.

The objective of the utility model is to expand the arsenal of tools for a similar purpose.

This problem is solved due to the fact that the device for measuring the active resistance, as in the prototype, contains a clock pulse generator, a counter, a reference voltage source, while the first output of the capacitor is connected to the first input of the comparison device and the output of the operational amplifier, the second output of the capacitor is connected with the first output of the measured resistance, the first output of the reference resistor and the input of the operational amplifier, the first input of the control device is connected to the output of the comparison device, second second control input device connected to the output of the counter, a clock pulse generator output is connected to counter input, the decoder output is connected to the input of the indicator.

According to a utility model, the output of the reference voltage source is connected to the first terminal of the switch, the second terminal of which is connected to the input of the inverting amplifier, the third terminal of the switch is connected to the second terminal of the measured resistance. The output of the inverting amplifier is connected to the second output of the reference resistor. The first output of the control device is connected to the input of the decoder, and the second output of the control device is connected to the fourth output of the switch.

Compared with the prototype, the proposed device can reduce the measurement error due to the use of fewer structural elements. In addition, the use of a single counter and switch in the circuit instead of two counters and keys as in the prototype allows to reduce the measurement time. But in general, the inventive device for measuring active resistance has increased reliability with a lower mass and dimensions.

In FIG. 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 switch 2 (Π), an inverting amplifier 3 (DI), an exemplary resistor 4, an operational amplifier 5 (OU), a comparison device 6 (US), a device are connected in series control 7 (УУ), decoder 8 (Дш), indicator 9 (Indus). A capacitor 10 is included in the feedback circuit of the operational amplifier 5 (op-amp). The measured resistance 11 and the operational amplifier 5 (op-amp) are connected in series to the switch 2 (P).

To the generator of clock pulses 12 (GTI) are connected in series counter 13 (MF) and control device 7 (UE). The second output of the control device 7 (UE) is connected to the fourth output of the switch 2 (P).

The reference voltage source 1 (ION), switch 2 (P), inverting amplifier 3 (IU), operational amplifier 5 (OU), comparator 6 (US), control device 7 (UU), decoder 8 (Dsh), counter were used 13 (MF), Clock Generator 12 (GTI) of Analog Devices; VISHAY indicator 9 (Ind).

The proposed device operates as follows. To measure the active resistance in the first integration cycle, the switch 2 (P) is in position 14. In this position, the operational amplifier 5 (op-amp), the capacitor 10 and the measured resistance 11 form a voltage integrator. From the output of the reference voltage source 1 (ION), the reference voltage U ₀ through the measured resistance 11 is supplied to the input of the operational amplifier 5 (OA). The integration time t ₁ (first cycle) is fixed using a control device 7 (UE), a counter 13 (MF) and a clock generator 12 (GTI). The voltage at the output of the operational amplifier 5 (OS), at the end of the first integration step, 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 voltage integrator formed by the measured resistance 11 and the operational amplifier 5 (op amp), in the feedback circuit of which a capacitor 10 is included, in the first integration cycle;

t ₁ is the integration time of the first measure;

R _x - measured resistance 11;

C is the capacitance of the capacitor 10;

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

After the end of the first cycle, the control device 7 (UE) puts the switch 2 (P) in position 15 and at the same time starts a new countdown. From this moment begins the second integration cycle. In this cycle, the voltage integrator is formed by an exemplary resistor 4 and an operational amplifier 5 (op amp), in the feedback circuit of which a capacitor 10 is connected. From the output of the reference voltage source 1 (ION), the reference voltage U _{0 is} supplied to the input of the inverting amplifier 3 (DUT), which inverts the voltage (reverses the polarity of the voltage) and amplifies the signal level. The signal from the output of the inverting amplifier 3 (DUT) through the model resistor 4 is fed to the input of the operational amplifier 5 (DU). The voltage at the output of the operational amplifier 5 (OS) at the end of the second integration cycle is expressed by the formula [Application of 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 k is the gain of the inverting amplifier 3 (DUT)

where τ ₂ is the integration time constant of the integrator formed by the model resistor 4 and the operational amplifier 5 (op-amp), in the feedback circuit of which a capacitor 10 is included, in the second integration cycle;

t _x is the integration time of the second clock;

U _IU - voltage from the output of the inverting amplifier 3 (IU);

R ₀ - reference resistor 4.

Based on the fact that U _I = U _II (since at the beginning of the second cycle the voltage at the output of the operational amplifier 5 (OA) is equal to the voltage at the output of the operational amplifier 5 (OA) at the end of the first cycle, 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 11 is:

The result is an inverse relationship between the integration time of the second clock and the measured resistance 11. Over time t _{x, the} counter 13 (Сч) counts the number of pulses N that are received from the output of the clock generator 12 (GTI):

N = f _GI · t _x ,

f _GI - the frequency of the clock generator 12 (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 (UE) from the output of the comparison device 6 (US). At the same time, the receipt of data from the counter 13 (MF) is stopped, after which the information from the output of the control device 7 (CU) is fed to the input of the decoder 8 (L), where it is converted to the necessary code, which is fed to the input of the indicator 9 (Ind), s by which there is a visual display of the measured value of the active resistance 11.

Claims (1)

The device for measuring the active resistance contains a clock generator, a counter, a reference voltage source, while the first output of the capacitor is connected to the first input of the comparison device and the output of the operational amplifier, the second output of the capacitor is connected to the first output of the measured resistance, the first output of the reference resistor 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 counter, exit the clock generator is connected to the counter input, the decoder output is connected to the indicator input, characterized in that the output of the reference voltage source is connected to the first output of the switch, the second output of which is connected to the input of the inverting amplifier, the third output of the switch is connected to the second output of the measured resistance, the output the inverting amplifier is connected to the second output of the model resistor, the first output of the control device is connected to the input of the decoder, the second output of the control device with one with the fourth pin of the switch.

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