Embodiments of the invention relate to non-clamping method and apparatus for positive identification of a dead insulated and/or armoured electrical underground cable with twisting multi-conductor in excavation joint pit or cable basements in utility power substations.
Cable identification is defined as the positive selection of a particular cable that lies within a bunch of cables, and is necessary when cables need to be diverted for reasons such as, but not limited to, re-routing of roads, construction of culverts, looping in and out to a new substation from an existing distribution network and facilitating cable fault repairs.
Cable identification at cable termination in electric utility substation is straight-forward, however, cable identification at intermediate cable portions is more complicated especially if the intermediate cable portions are buried underground together with many similar power utility cables in close proximity in urban areas due to congestion and if underground conditions are complex. Accordingly, underground cable identification in urban areas is fraught with difficulties and prone to wrong identification.
Many existing cable identification methods, known as current transducer (CT) type, identify the dead cable mainly by determining current pulse polarity. Examples are described by U.S. Pat. No. 3,924,179, US Patent Application Publication No. 2004/0145486 A1. CT type methods face many issues: CT clamping must be in the correct direction—incorrect clamping direction will result in identification of wrong cable; the risk of incorrect clamping direction is increased if a cable in a joint pit has a ‘S’ shape or ‘U’ turn route; CT clamping contacts can become unreliable due to dust and dirt in the joint pit. Any clamping method including non-CT type such as EP Patent Application Publication EP1014099 A2 requires every cable to be tested (clamped) be fully excavated which is not always possible especially in highly congested urban areas.
Certain other methods, known as audio type (AT), apply audio frequency signal (tone) to cable conductors and use a probe to pick up the tone in field to do cable tracing or identification without clamping around the cable under test. Some examples are described by U.S. Pat. Nos. 7,116,093, 5,887,051, 6,946,850, US Patent Application Publication No. 2010/0176794, CA 2537927A1/WO 2004/079377A2, U.S. Pat. No. 6,163,144, U.S. Pat. No. 6,127,827, GB 889452 A. These publications are mostly related to communication wire tracing, low voltage live power wire tracing or specific Digital Signal Processing (DSP) technique like compressed filtration. They are not relevant to power utility cables with armouring, twisting conductors and wide voltage range from LV (such as 400VAC) to HV (such as 66kVAC) and they do not provide a reliable method to identify dead power utility cables from its adjacent power utility cables of close proximity, live or dead.
According to one embodiment, a non-clamping method for identification of target dead underground power cable is provided. The method comprises:
According to one embodiment of the invention, a receiver for identification of target dead underground power cable is provided. The receiver comprises:
According to one embodiment of the invention, a transmitter for identification of target dead underground power cable is provided. The transmitter comprises:
According to one embodiment of the invention, a system for cable identification is provided. The system comprises:
Embodiments of the invention are disclosed hereinafter with reference to the drawings, in which:
In the following description, numerous specific details are set forth in order to provide a thorough understanding of various illustrative embodiments of the invention. It will be understood, however, to one skilled in the art, that embodiments of the invention may be practiced without some or all of these specific details. In other instances, well known process operations have not been described in detail in order not to unnecessarily obscure pertinent aspects of embodiments being described. In the drawings, like reference numerals refer to same or similar functionalities or features throughout the several views,
In block 1002, a complete circuit is formed with a pair (two) 23 of a plurality of conductors 28 (
In block 1004, using a transmitter 100, an audio frequency current signal is injected into the completed circuit. The audio frequency current signal is to generate an audio frequency magnetic flux signal on a surface of the target dead power cable 25. To this purpose, a pair of tone output wires 101 is provided at the transmitter 100 and is connected to the pair of conductors 23 via a cable termination 21. The applied audio frequency current signal travels through the complete circuit formed in block 1002. The earth path is excluded from the complete circuit in which the applied audio frequency current signal flows.
In block 1006, the circuit formed in block 1002 is verified for circuit completion. This verification may be performed by the transmitter 100 which is configured to perform a circuit completion check. The transmitter 100 is further configured to provide suitable notifications such as by LED indicator, to present the verification result, i.e. whether the circuit is verified complete or incomplete.
In block 1008, in the FES 10 with the target dead cable known at cable termination, the receiver 200 and/or transmitter 100 may be calibrated to maximize spatial resolution of distinctness. For example, if the peak amplitude of a detected audio frequency magnetic flux signal produces a display output of less than 50% of the displayable length, e.g. less than 5 LED bar indicators, the receiver 200 and/or the transmitter 100 is adjusted to increase output amplitude so that the detected peak amplitude of the audio frequency magnetic flux signal produces a normalized level display output of about 60%, e.g. 6 LED bar indicators. The calibration can be done via adjusting switch 106 in
In block 1010, at an excavated joint pit 11 which at least partially exposes intermediate portions of various power cables 22, 25, the wall and floor of the joint pit 11 and along every exposed cable surface in the joint pit 11 are screened to locate a peak amplitude of audio frequency magnetic flux signal which is generated by the applied audio frequency current signal in block 1004. This is done by using an audio pick-up coil 210 which is electrically coupled to a receiver 200. The receiver 200 includes a speaker that is configured to broadcast a detected audio frequency magnetic flux signal, and a display device 208 (
In block 1012, identification of the target dead power cable 25 takes place by comparing peak amplitude of audio frequency magnetic flux signal detected at each cable against that of its spatially-adjacent cables. Starting from the location or cable where the peak amplitude of audio frequency magnetic flux signal was detected (in block 1010) or starting from a random cable, for each of the neighbouring cables spatially-adjacent to this location or cable, peak amplitude of audio frequency magnetic flux signal detected at the surface of each neighbouring cable are ascertained and compared. During this comparison, signal gain level control of the receiver 200 and transmitter 100 should not be adjusted.
In practice, a pick-up coil 210 is longitudinally run along the lengthwise direction, for example 1.5 m to 2 m along the surface of each spatially-adjacent neighbouring cable. If an audio frequency magnetic flux signal is detected, the display device 208 of the receiver 200 will display the signal amplitude which cycles through a peak to a trough value as the pick-up coil 210 is moved along the cable length.
A power cable is successfully identified as the target dead power cable when the peak amplitude of audio frequency magnetic flux signal of the target power cable exceeds any detected peak amplitude of audio frequency magnetic flux signal of its spatially-adjacent cables by more than about fifty per cent (50%). As an illustrative example, peak amplitude of audio frequency magnetic flux signal detected from the target dead power cable may produce a display output of 6 bar indicators while peak amplitude of audio frequency magnetic flux signal detected from neighbouring cables spatially-adjacent to the target dead power cable may produce a display output of 3 or less bar indicators.
To prevent detecting and using irrelevant magnetic flux signals resulting from unrelated dead power cable identification task(s) that are being performed in the vicinity at the same time and using the same transmitter and receiver device model, block 1012 includes extracting a decoded key from a detected audio frequency magnetic flux signal and ascertaining whether the decoded key matches a shared key stored in the receiver 200. As the shared key is exclusively stored in the transmitter 100 and receiver 200 paired therewith, this procedure ensures that the detected signal is resulted from the transmitter being used in block 1004 and provides differentiation from unrelated signals resulting from other transmitters being concurrently used. If the decoded key does not match the stored key, a notification is presented. Such notification may take on one or more forms including, but not limited to, display an error indication on the display device, inactivate the display device 208 to prevent display of the detected audio frequency magnetic flux signal. If the decoded key matches the stored key, the display device 208 of the receiver 200 is allowed to display the amplitude of the detected audio frequency magnetic flux signal.
It is to be appreciated that the pick-up coil 210 may be used individually or in conjunction with a magnetic shield 221 to reduce interference due to neighbouring magnetic fields.
To connect the transmitter 100 to the target dead power cable, alligator-clip-banana-plugs 101 are used to electrically couple the transmitter 100 output to the termination 21 of the pair of conductors of the target dead power cable. The termination 21 is in turn electrically coupled to the pair of single phase conductors 23 of the dead power cable 25.
A micro controller unit (MCU) 111 is provided with a crystal 112 configured to generate an audio frequency voltage signal e.g. 1023 Hz tone 115. The MCU 111 is also configured to monitor battery voltage and control a display circuitry which includes indicator LEDs (power status LED 113b, tone pattern LED 113c, battery charging indication LED 113d). The MCU 111 may be provided with a 30 ppm 3.2768 MHz crystal 112 as the root source of clock.
A current selector circuitry 116a is electrically coupled to the MCU 111 and used to configure the preset peak pulse amplitude for the audio frequency current signal 117 to be output from the transmitter 100. The current selector circuity 116a, amplifier 116b and indicator 113a provide a current sensing circuitry configured to verify whether a circuit connected to the transmitter 100 is complete and presents the verification result via indicator 113a.
A constant peak current source circuitry (constant peak current driver) 116c is electrically coupled to the current selector 116a and configured to convert an audio frequency voltage signal into an audio frequency current signal having the preset peak current pulse amplitude.
An output protection circuitry 116d is electrically coupled to the constant peak current source circuitry 116c and configured to prevent damage to the transmitter 100 due to any over-voltage, over-current and transient cable inductance kickbacks.
A pair of output terminals 117 are electrically coupled to the output protection circuitry 116d and configured to inject the transmitter output, i.e., audio frequency current signal, into a pair of conductors 23 of a target dead power cable.
A memory circuitry 114 is electrically coupled to the MCU 111 and configured to store a shared key which is exclusive to the transmitter 100 and a receiver 200 paired therewith. The MCU 111 is configured to read the shared key from the memory 114 and encode the shared key into the audio frequency voltage signal derived from the stable clock source, i.e. the crystal 112,
An input terminal 216a is configured to receive picked-up signals from the pick-up coil 210, which picks up both audio frequency magnetic flux signal and electromagnetic noises such as mains hum and its harmonics.
An amplifier circuitry 216b is electrically coupled to the input terminal 216a and configured to amplify a picked-up signal by a user-adjustable gain via an external gain selector switch 215.
A by-passable switched capacitor analogue ultra-narrow bandpass filter 214, 219a is electrically coupled to the amplifier circuitry 216b for filtering the amplified picked-up signal and, more particularly, extracting an audio frequency magnetic flux signal of a predetermined frequency from the amplified picked-up signal.
An internal gain calibrator circuitry 219d is electrically coupled to the by-passable switched capacitor analogue ultra-narrow bandpass filter 214, 219a and configured with filtered signal path to generate a factory-calibrated magnitude for the audio frequency magnetic flux signal from the filtered picked-up signal, i.e. an output of the filter 219a. The internal gain calibrator circuitry 219d is calibrated in factory for filtered signal from ultra-narrow bandpass filter 219a to match a normalized 6-LED-bar on the surface of 2-metre utility power cable sample that is most popularly used.
A speaker circuitry 219c, 217 is electrically coupled to the gain calibrator circuitry 219d and configured to receive and broadcast the calibrated and filtered picked-up signal or the unfiltered picked-up signal, i.e. an output of block 219d.
The output signal from block 219d is processed by a pre-ADC: (Analogue Digital Conversion) conditioning circuitry 219b which then transmits an ADC input 211e to a micro-controller unit (MCU) system 211c.
The MCU 211c is configured to generate the switched capacitor filter clock 211d, monitor battery voltage and control the indicator LEDs. A 30 ppm 3.2768 MHz crystal 211b as the root source of clock is electrically coupled to the MCU 211c. The MCU 211c includes an Analogue to Digital Converter (ADC) which is further configured to digitise the calibrated and filtered picked-up signal, i.e. an output of block 219d or unfiltered picked-up signal which has been conditioned by block 219b prior to input to the ADC.
For the filtered picked-up signal, the ADC of the MCU 211c is further configured to digitise the output of the internal gain calibrator circuitry 219d based on a plurality of piecewise linear sensitivity relationships between the output of the pre-ADC circuitry 219b and peak amplitude to be displayed on the display device 208, i.e., LED bar indicators.
A display circuitry 218 (including LED bar tone magnitude display device 208) is electrically coupled to the MCU 211c and configured to receive an output of the MCU 211c, i,e. the digitised output of the gain calibration circuitry 219d. A visual indication of this output is provided on the display device 208 in which the displayed magnitude of the visual indication is correlated to an amplitude of an audio frequency magnetic flux signal comprised in the picked-up signal which was received at 216a and has since been filtered by 219a.
A volume controller 213 is electrically coupled to the speaker circuitry 219c, 217 for adjusting a volume output of a speaker 217. The volume controller 213 is decoupled from the display circuitry 218 to prevent the volume controller from adjusting the displayed amplitude on the display device 208.
A memory 211a is electrically coupled to the MCU 211c and configured to store a shared key which is exclusive to the receiver 200 and the transmitter 100 paired therewith. The MCU 211c is configured to extract a decoded key from the calibrated audio frequency magnetic flux picked-up signal, i.e. output of block 219b, and ascertain whether the decoded key matches the shared key stored in the memory 211a of the receiver 200. If the decoded key does not match the shared key stored in the memory 211a, a notification is presented. Such notification may take on one or more forms including, but not limited to, display an error indication on the display device, inactivate the display device 208 to prevent display of the detected signal amplitude, etc.
Embodiments of the invention are advantageous in view of at least the following:
The method and apparatus are factory calibratable to the most popular power cable type in utility circuits to form a normalised signal magnitude level.
The method and apparatus are field calibratable to different underground multiconductor power cable types to overcome variant signal flux attenuation effect due to the differences from the cable type.
The method and apparatus use a Piecewise Linear Multiple Virtual Sensitivity (PLMVS) relationship to form normalised signal level, block floor noise and boost spatial resolution for cables in close proximity.
The method is not subject to various interferences as explained below:
It is to be understood that the embodiments and features described above should be considered exemplary and not restrictive. Many other embodiments will be apparent to those skilled in the art from consideration of the specification and practice of the invention. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. Furthermore, certain terminology has been used for the purposes of descriptive clarity, and not to limit the disclosed embodiments of the invention. The entire disclosures of all references, applications, patents, and publications cited above are hereby incorporated by reference.
Number | Date | Country | Kind |
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10201602767R | Apr 2016 | SG | national |
This application is a continuation application of International Application No. PCT/SG2017/050193 filed on Apr. 5, 2017, which claims priority to and the benefit of the filing of Singapore Patent Application No. 10201602767R filed on Apr. 8, 2016, and the specification and claims thereof are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/SG2017/050193 | Apr 2017 | US |
Child | 16151649 | US |