SU1501289A1 - Device for measuring high-frequency signal level in power supply lines - Google Patents

Abstract

The invention relates to telecommunications. The purpose of the invention is to improve the measurement accuracy by calibrating the measurement when subjected to power frequency currents. The device contains a conductor 1, power supply line 2, load 3, industrial frequency source 4, source 5 controlled HF signals, measuring transreactors 6 and 9 with split magnetic cores 7 and 10 and with multi-turn secondary windings 8 and 11, selective microvoltmeter 12, switch 13 and a calibration block 14, consisting of Mr. 15 RF signals, an ammeter 16 and capacitors 17 and 18. The device operates in succession in two modes: calibration and measurement. In the calibration mode with respect to currents caused by sources 4 or 5, windings 8 and 11 are turned on. Therefore, the algebraic difference of the emf caused by these currents will be zero, and the calibration factor will be determined only by the current in the ammeter 16 and the input voltage of the microvoltmeter 12. In the measurement mode, the calibration unit 14 is turned off and the windings 8 and 11 are connected to each other according to The EMF caused by the current from sources 4 and 5 in the conductor 1 of line 2 with load 3 were incurred. 2 Il.

Description

(/)

(fiuel

3150

carved magnetic cores 7 and Yun with multi-turn secondary windings 8 and 11, a selective microvoltmeter 12, a switch 13 and a calibration block 14 consisting of g. 15 RF signals, an ammeter 16 and capacitors 17 and 18. The device operates in series in two Modes: Calibration and Measurement. In the calibration mode with respect to currents caused by sources 4 or 5, windings 8 and 11 are turned on. Therefore, algebra and Invention relates to telecommunications and can be used in communications devices using power lines.

The purpose of the invention is to improve measurement accuracy by calibrating measurements when subjected to power frequency currents.

FIG. 1 shows the structural electrical circuit of the device for measuring the level of high-frequency signals in the power supply lines in measurement mode i in FIG. 2 - the same in the calibration mode.

The device contains a current conductor 1 of power supply line 2, containing load 3, source 4 of industrial frequency and source 5 of controlled high-frequency signals, the first measuring transceiver 6 with a split magnetic conductor 7 and a multi-turn secondary winding 8, the second measuring transreactor 9 with a split magnetic conductor 10 and many - a coil winding 11, a selective microvoltmeter 12, a switch 13 and a calibration block 14, consisting of a generator of .15 high-frequency signals, an ammeter 16 and the first 17 and second 18 capacitors in.

A device for measuring the level of high-frequency signals in power supply lines works as follows.

In the device calibration mode, the positions of the first and second terminals of the calibration block 14, as well as the switch 13, correspond to those indicated in FIG. 2. The secondary windings 8 and 1 1 of the first 6 and second 9 transreact .-) 2 "9

Testing the emf caused by these will be equal to zero, and the calibration coefficient will determine the TOjH.Ko current in the ammeter 16 and the voltage at the input of the microvoltmeter 12. In the measurement mode, the calibration unit 14 is turned off and windings 8 and 11 are connected between according to

10 so that the EMF caused by the current from sources 4 and 5 in the conductor 1 of line 2 with the load 3 folded. 2 Il.

The ditch is interconnected in series and counter.

The sections of the tokopropod 1, as well as the first 17 and second 18 capacitors form a bridge circuit, and the generator 15 and ammeter 16 are included in its diagonal. The sections between the points of connection of the outputs of the calibration block 14 are about o / h of the length, so the bridge circuit is balanced. Using a generator 15 and an ammeter 1.6, set the current of the calibrated level for a specific frequency under study.

As a result of the fact that the bridge circuit containing the calibration block 14 is balanced, the entire calibration current passes only through the indicated sections of the conductor 1, and currents of the same magnitude, equal to half of the total current and directed oppositely, flow through each of the sections.

Therefore, the voltage drop caused by the current of the calibration node at conductor points is zero. This indicates a lack of interconnection between currents caused by a generator.

15 and source 4 or source 5. At the same time, the algebraic sum of the emf induced in the opposite multi-turn secondary windings B and 11, caused by the generator current 15, is proportional to

the sum of the currents, the passage of the aforesaid along the indicated sections of the conductor, 1.

At the same time, with respect to currents caused by sources 4 or 5, the multi-turn secondary windings 8

and 11 included counter. Therefore, the algebraic difference of the emf caused by these currents is zero. Due to this, the coefficient of 11) the tsikentiment is determined only by the current in the ammeter 16

fig 2

Claims (1)

Claim A device for measuring the level of high-frequency signals in power lines, comprising a selective microvoltmeter, a first measuring transreactor with a split magnetic circuit covering the power line conductors, and a multi-turn secondary winding, the first terminal of which is connected to the first terminal of a selective microvoltmeter, characterized in that, in order to improve the accuracy measurements due to calibration of measurements under the influence of currents of industrial frequency, the second measuring transreactor with split with a magnetic circuit covering another section of the current supply line of the power supply line and a multi-turn secondary winding, a switch and a calibration unit containing sequentially connected high-frequency signal generator and an ammeter, the second output of which is connected to the first plates of the first and second capacitors, the second plates of which _{15 are} connected respectively to the first and the second terminals of the calibration block, the third terminal of which is the second output of the high-frequency signal generator and is connected to there is a power supply line between its sections covered by split magnetic circuits of the first and second measuring transreactors, while the second terminal of the multi-turn secondary winding of the first measuring transreactor is connected to the first terminal of the switch, the second and third conclusions of which are connected to the terminals of the multi-turn secondary winding of the second measuring transreactor, and the second terminal of the selective microvoltmeter is connected to the fourth terminal of the switch.