CONNECTIVITY VERIFICATION FOR AN ABSENCE OF VOLTAGE TESTER SYSTEM

Abstract

A permanently installed absence of voltage tester (AVT) may include a connectivity verification system for verifying the connectivity of system cable leads to the main power lines in electrical equipment. An installed AVT may indicate whether the electrical equipment is in an electrically safe state without first requiring direct access to the equipment. One step in the AVT test procedure may include connectivity verification by the connectivity verification system, which may include a sub-procedure to confirm that the installed AVT is directly coupled as intended with direct connection to the equipment being monitored. The connectivity verification system may validate that the AVT is measuring the actual voltage on the power lines of the electrical equipment and has not registered a no-voltage condition due to an unknown disconnection error or installation failure.

Description

Claims

1. A method for verifying connectivity of an absence of voltage tester to power lines in electrical equipment, the method comprising: generating and modulating a digital signal at predetermined frequency ranges using digital signal generator/modulator;converting the digital single-ended signal to a differential RF signal;coupling the RF differential signal with the high-voltage power line via narrow-band, band-pass LC resonance filtertransmitting the differential RF signal across a pair of wire leads, each wire in the pair of wire leads being connected to a power line having a same phase;detecting the change in the RF signal amplitude and/or the phase using an RF detector/demodulator; anddetermining whether each wire in the pair of wire leads is connected to a same power line via analyzing the change to the RF path characteristic impedance.

2. The method of claim 1, wherein the change in the RF path characteristic impedance of the circuit is determined by a change in amplitude and/or phase of the output of the RF detector signal.

3. The method of claim 2, wherein determining whether each wire in the pair of wire leads is connected to the same power line based on an amplitude and/or phase of the output comprises: comparing the RF detector output to a dynamic decision threshold that is being calculated based on a linear regression function that takes system temperature as a variable; andverifying that each wire in the pair of wire leads is connected to the same power line when the output is above the connectivity decision line.

4. The method of claim 2, wherein determining whether each wire in the pair of wire leads is connected to the same power line based on an amplitude and/or phase of the output comprises: comparing the RF detector output to a decision line/threshold; andverifying that each wire in the pair of wire leads is connected to the same power line when the output is above the connectivity decision line.

5. The method of claim 1, further comprising: prior to transmitting the RF signal across the circuit, connecting the RF signal generator to the circuit using an analog multiplexer/demultiplexer.

6. The method of claim 1, further comprising: prior to transmitting the RF signal across the circuit, converting the single-ended signal into differential-balanced signal.

7. The method of claim 1, further comprising: prior to connecting the RF signal across the power lines, isolating the low-voltage RF signal from the high-voltage power lines via a discreet, narrow-band, resonance band-pass-filter.

8. The method of claim 5, further comprising: prior to connecting the RF signal generator to the circuit, testing the tester by analyzing the output of the RF detector with the RF signal generator off.

9. The method of claim 5, further comprising: prior to connecting the RF signal generator to the circuit, testing the tester by analyzing the output of the RF detector with the RF signal generator on.

10. A connectivity verification system comprising: a radio frequency (RF) signal generator configured to generate an RF signal;an RF detector in communication with the RF signal generator; anda circuit, having a characteristic impedance, coupled to the RF signal generator via another circuit configured to convert the RF signal to a differential RF signal and RF detector, the circuit including a pair of wire leads, each wire in the pair of wire leads being connected to a same phase wire of a power line;wherein connectivity of the pair of wire leads to the same phase wire of the power line is verified by analyzing a change in the characteristic impedance.

11. The connectivity verification system of claim 10, wherein the circuit includes at least one LC Balun configured to convert the RF signal from single-ended to differential, wherein each output of the LC Balun is connected to one wire in the pair of wire leads through an LC resonance filter.

12. The connectivity verification system of claim 10, wherein the circuit includes a signal transformer including a primary side and a secondary side having at least two secondary windings, the primary side of the signal transformer being driven by the RF signal generator, each wire in the pair of wire leads belonging to the same phase connects to one side of the two secondary windings, wherein other sides of the secondary windings connect to a rectifier and the RF detector.

13. The connectivity verification system of claim 8, wherein the circuit includes a signal transformer including a primary side and a secondary side having at least a first secondary winding and a second secondary winding, the primary side of the signal transformer being driven by the RF signal generator, the first secondary winding being connected across the two wires in the pair of wire leads belonging to the same phase, the second secondary winding being connected to the RF detector.