SU617732A1 - Low-frequency ac sensor - Google Patents

Description

one

The invention relates to devices for converting AC power at the input to AC power at the output, for example, to measure current or voltage, in particular to devices for measuring AC low frequency current.

Current sensors are known that use the principle of a direct current transformer 1. Such sensors are installed in circuits where a current of the same sign flows. It is not possible to use these sensors in circuits where alternating current flows, because when the polarity of the measured current changes, the secondary windings of the current transformers entering the sensor produce large counter-directed voltages at which there is no current in the secondary windings. Overvoltages are applied until one of the current transformer cores is saturated. As a result, loss of information is unacceptable.

The closest to the invention is a low frequency alternating current sensor containing two ferromagnetic cores, common nervous and separate secondary windings 2. The disadvantage of this sensor is its inability to use it to measure high frequency currents. Overvoltage occurs in the secondary windings when the current direction changes in the primary winding, which leads to loss of information.

The aim of the invention is to limit overvoltage 5 on the secondary windings and to avoid loss of information. For this, two sources of constant voltage, two capacitors and two connected in series

0 pairs of diodes, the secondary windings being connected in series to each other through two load resistors, the middle terminal of the connection of the load resistors is connected to the middle terminal of series-connected constant voltage sources, each of which is bridged by a capacitor, between the beginning of the secondary winding on the first core and the end of the secondary winding on the second core

0 includes two pairs of diodes, with the average output of one pair of diodes connected by anodes connected to the negative terminal of the first constant voltage source, and the average output of the other pair of diodes,

5 connected by cathodes connected to the positive terminal of the second constant-voltage source.

The drawing shows the principle of the proposed sensor.

Q It contains two ferromagnetic cores 1 and 2, primary winding 3, secondary windings 4 and 5, load resistors 6 and 7, sources 8 and 9 of constant voltage, capacitors 10 and 11, and two pairs of diodes 12 and 13, 14 and 15 , connected in each pair in series - counter.

When the polarity of the measured current changes, the secondary current of the first transformer is closed through diode 12, capacitance 10 and resistor 6. Secondary current of the second transformer is closed through source 16, diode 12, capacitor 10 and resistor 7. The amount of overvoltage is limited by the voltage of sources 8 and 9 which are included in the direction of locking the diodes 12 and 13. Overvoltages on the secondary windings 4 and 5 may have different signs depending on the direction of the measured current (current in the primary winding). With a positive overvoltage (plus the start of winding 4), the secondary current is closed through diodes 12 and 13, with a negative through diodes 14 and 15. Diodes 12-15 open when the overvoltage exceeds the voltage across the capacitors 10 and 11. At the end The transient diodes 12-15 are closed, and the aperture current, for example, of the first transformer is closed along the circuit: resistors 6 and 7, winding 5 of the second transformer, power supply 16. This circuit is possible because the second transformer is saturated and the potential difference across its secondary windingclose to 0. A similar process occurs for the second transformer.

Thus, a special circuit of the currents of the secondary windings of each transformer is created. A contour occurs when the secondary voltage reaches a certain predetermined value, which can be

choose at any level. In this case, the current always closes through the load resistors, and information loss does not occur.

Claims (2)

1. Belitska MS, Limanov Ye. A. Transformers of direct current and voltage for high-voltage converters. “Energie, 1964, p. 39 2. USSR author's certificate Yao 400959, H 02M 5/10, 1966. J 12 /four W / J "H 15 - 16 o