CS267802B1 - Condensate leakage resistance measurement device Ic. 12 tors with a value greater than 10 ohms - Google Patents

Abstract

The device relates to the field of measurement technology. The essence of the device is that a source of stable direct current voltage is connected to the first measuring terminal via a switching relay, while the second measuring terminal equipped with a charging resistor is connected to the input of an amplifier, the output of which is connected via a voltage-to-frequency converter and an evaluation unit with a display unit. In this case, the control inputs of the voltage-to-frequency converter, the evaluation unit and the display unit are connected to the control output of a frequency exchange, the switching output of which is connected to the switching input of the exchange, the switching output of which is connected to the switching input of the switching relay.

Description

The invention relates to a device for measuring the leakage resistance of capacitors with a value higher than 1 z. than 10 ohms, containing a source of stable DC voltage.

Until now, the leakage resistances of high-quality capacitors have been measured using electrometers or picoammeters.

The disadvantage of electrometers is their relatively low accuracy of measured values. The disadvantage of full meters is mainly their high price, which results from a very demanding design. In addition, when measuring leakage resistances higher than 10 ^ ⁴ ohms, their sensitivity does not suit most picoammeters.

Many of these disadvantages are eliminated by the capacitor leakage resistance measuring device according to the invention, the essence of which is that a stable DC voltage source is connected to the first measuring terminal via a switching relay, while an amplifier input is connected to the second measuring terminal provided with a charging resistance it is connected via a voltage to frequency converter and an evaluation unit with a display unit. The control inputs of the voltage-to-frequency converter, evaluation units and display units are connected to the control output of a frequency control panel, the switching output of which is connected to the switching input of a switching relay.

The advantage of the device is its high accuracy at relatively very low acquisition costs.

An exemplary embodiment of the device according to the invention is shown in the attached figure, which is a block diagram of the device.

The stable DC voltage source 1 is connected to the first measuring terminal 3 via a switching relay, while the input of the amplifier 7 is connected to the second measuring terminal 4 provided with a charging resistor 12, the output of which is connected via a voltage to frequency converter 8 and an evaluation unit 9 ^{with a} display unit. 1 0. The control inputs of the voltage-to-frequency converter £, the evaluation unit £ and the display unit 10 are connected to the control output of the frequency control panel 11, the switching output of which is connected to the switching input of the spin relay 2. The ideal terminals 3, 4 are connected in the figure. capacitor 5 and leakage resistor 6.

The measured encoder, which is represented by an ideal capacitor 5 and a parallel resistor £, is connected to the measuring terminals 3. The switching relay 2 is controlled from the frequency control panel 11. After pressing the start button, which is not indicated in the figure, it is part of the frequency control panel, the frequency control panel 1 1 closes the switching relay 2, the capacitor 2 ^is charged via the charging resistor 1 2. After the time given by the frequency control panel 1 1, for example 120 s, the capacitors are charged. and a voltage-to-frequency converter is applied to the converter 8. The stress has an exponential course typical of a derivative cell. In the evaluation unit 9, the last phase of the conversion of the analog voltage on the charging resistor 12 to the number of pulses takes place, which is then shown on the display of the display unit 10. This number of pulses is inversely proportional to the leakage resistance value R, which is calculated numerically from the mathematical relationship obtained instrument calibration. The relationship has a general shape

In / 1 - K2, K3 / where it represents the time for which the capacitor is charged, the broken capacity of the condensate o r u 2

In is the natural logarithm is the number of pulses that is displayed on the display of the display unit Jj] j / is the calibration constant created during the calibration of the instrument

For the value of capacitors 5 with leakage resistance R and capacitance C, the relationship is given

CS 267002 01 independent of the size of the capacity C, if the product for the error is up to 5%. lim is given the use of the described device for high values of leakage resistances R. For lower quality capacitors it is suitable to supplement the device with a capacity meter control microcomputer, which ensures the comfort of measurement and its accuracy.

Claims (1)

BACKGROUND OF THE INVENTION Device for measuring the leakage resistance of a capacitor with a value higher than 10 ohms, comprising a source of stable DC voltage, characterized in that the source / 1 / of stable DC voltage is connected to the first measuring terminal / 5 / via a switching relay / 2 /, the measuring terminal / 4 / provided with a charging resistor / 12 / is connected to the input of the amplifier / 7 /, the output of which is connected via a voltage / frequency converter / evaluation unit / 9 / with a display unit / 10 /, while the control inputs of the converter / 8 / voltage per frequency, evaluation units / 9 / and display units / 10 / are connected to the control output of the frequency control panel / 11 /, the switching output of which is connected to the switching input of the switching relay / 2 /.