Power line universal monitor

US 20080077336A1
Filed: 09/25/2006
Published: 03/27/2008
Est. Priority Date: 09/25/2006
Status: Abandoned Application

First Claim

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1. A Power Line Universal Monitor (PLUM) sensor module for installation on and removal from an energized High Voltage AC power conductor for accurately measuring Global Positioning Satellite (GPS) synchronized voltage, current, phase, frequency and derived quantities on said AC power conductor, said PLUM comprising:

a plurality of sensors for make GPS synchronized measurements of said conductor voltage, current, phase, frequency and derived fundamental and harmonic quantities simultaneously at a plurality of predetermined times determined by the utility Wide Area Network Supervisory Control And Data Acquisition (SCADA) and Relaying application requirements;

an RF signal transmitter for transmitting said measurements to a Master Controller using a secure two-way RF signal;

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Abstract

The invention is primarily directed to hot-stick mountable wireless High Voltage Power Line Universal Monitors (PLUM) upon energized electrical power conductors. The PLUM wireless sensors monitor parameters associated with normal, overload and emergency operation of the power line. The present invention provides 0.2% metering grade voltage measurement accuracy through unique e-field measurements, synchronized through UltraSatNet Global Positioning Satellite (GPS) accuracy timing pulses. The invention further improves accuracy using a unique calibration technique during initial installation of the PLUM sensor modules. A PLUM master controller receives time-synchronized data from multiple modules within a substation and across a state-wide power grid for accurate post-fault, sequence-of-events analysis, high impedance fault signature analysis, and environmental and earthquake monitoring.

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45 Claims

1. A Power Line Universal Monitor (PLUM) sensor module for installation on and removal from an energized High Voltage AC power conductor for accurately measuring Global Positioning Satellite (GPS) synchronized voltage, current, phase, frequency and derived quantities on said AC power conductor, said PLUM comprising:
- a plurality of sensors for make GPS synchronized measurements of said conductor voltage, current, phase, frequency and derived fundamental and harmonic quantities simultaneously at a plurality of predetermined times determined by the utility Wide Area Network Supervisory Control And Data Acquisition (SCADA) and Relaying application requirements;
  
  an RF signal transmitter for transmitting said measurements to a Master Controller using a secure two-way RF signal;
- View Dependent Claims (2, 3, 4, 5)
- - 2. The PLUM of claim 1 further comprising:
    - a metallic housing mounted in surrounding relation to and conductively isolated from the associated conductor, anda plurality of hub capacitors for series-parallel connection, shielded from the environment in the hub space surrounding the high voltage AC power conductor, whereby a charging current is present on said housing due to the electric field of said high voltage AC power conductor and wherein said conductor voltage is measured by sensing a charging current through said plurality of hub capacitors.
  - 3. The PLUM of claim 2 further comprising:
    - a switch for bypassing charging of said hub capacitors; and
      
      a calibration sensor module with charging current measurement circuitry for accurately measuring current through a known precision high voltage resistance to ground, in order to account and calibrate for the influence of adjacent conductors and stray capacitances at the time of installation.
  - 4. The PLUM of claim 2 further comprising a fixed precision capacitor for measuring charging current through said high voltage AC power conductor while disconnecting charging current from the series-parallel hub capacitors, wherein a measured change in this charging current during operation allows dynamic calibration of the PLUM sensor during temporary stray capacitance changes due to various factors.
  - 5. Invention according to claim 2 wherein said PLUM sensor further includesa processor for accurately calculating the phase of each of said measurements at the high voltage AC power conductor while accurately retaining phase relationships between said measurements through GPS time synchronization.

6. A system for monitoring and controlling an energized high voltage power conductor at conductor potential and detecting possible high impedance faults, and pole-top auto-recloser operations, said system comprising:
- a sensor module for mounting upon and removal from said energized high voltage power conductor, said sensor module havingsampling circuitry for sampling the value of a variable parameter and determining the fundamental and harmonic content of said variable parameter, said sensor module further including a memory for storing the sampled value over selectable intervals of time (ranging from hours to days), in order to establish a harmonic signature and transient random variation for said variable parameter;
  
  a processor for monitoring changes in the stored harmonic signature of said variable parameter in order to determine the presence of a high impedance fault; and
  
  a transmitter for transmitting a fault trigger in response to said changes in the stored harmonic signature;
  
  a ground receiver, remote from said sensor module for receiving said fault trigger and actuating a control means in response thereto.
- View Dependent Claims (7, 8, 9, 10, 11, 12, 13, 14)
- - 7. The system of claim 6 wherein said transmitter transmits said fault trigger over a wide area network communications link using secure Code Division Spread Spectrum Multiple Access communications.
  - 8. The system of claim 6 wherein the sampling circuitry for sampling the value of a variable parameter includes circuitry for varying the interval of time over which said sampling occurs, such that the sensor module may sample over longer and/or shorter time intervals in response to said parameter exhibiting an abnormal variation of the harmonic signature.
  - 9. The system of claim 6 wherein the sensor module further includes circuitry for detecting and recording the total number of open/close operations of an auto-recloser switch coupled to said high voltage power conductor, said total number of open'"'"'close operations being transmitted to a power grid control operator.
  - 10. The system of claim 6 wherein said control means includes a relay actuator for interrupting the high voltage power supply.
  - 11. The system of claim 6 wherein said transmitter is comprised of a fiber optic communications link.
  - 12. The system of claim 8 wherein the number of samples taken over an interval of time is also variable in response to a predetermined rate of change of said parameter harmonic content.
  - 13. The system of claim 8 wherein said sampling circuitry is constructed and arranged to sample at least one or more harmonics of said variable parameter, and wherein said sampling interval of time is adequate to measure the highest desired harmonic content in order to distinguish a high impedance fault from normal load over-current.
  - 14. The system of claim 9 wherein said operator alarm comprises a remote telemetering interface for communicating a fault trigger alarm signal to a location remote from said ground receiver.

15. A system for fault detection, fault isolation, determination of sequence-of-events and service restoration, across a power grid, said system comprising:
- a plurality of sensor modules for mounting upon and removal from each of the energized high voltage AC conductors within the power grid;
  
  each of said sensor modules in the plurality comprising;
  
  GPS time level synchronization circuitry for causing said each of said sensor modules in the plurality to simultaneously measure fault indicating parameters on each of their associated high voltage AC conductors;
  
  a transmitter for transmitting signals from said sensor module commensurate with measurement of the fault indicating parameter;
  
  a remote controller separate and remote from the plurality of sensor modules, for receiving and comparing said signals all within the time constraints required for effective power grid protection; and
  
  a processor to generate a relay control signal for operating an automated switch or circuit breaker in response to a detected difference between said compared signals exceeding a predetermined threshold level.
- View Dependent Claims (16, 17, 18, 19, 20)
- - 16. The system of claim 15 wherein said time constraints comprise a time period not greater than that of 2 successive cycles of current when used for differential protection of a power grid substation transformer.
  - 17. The system of claim 15 wherein said remote controller further includes a transmitter for transmitting time-synchronizing signals to each of said sensors in the plurality, each of said modules including a receiver for receiving said time-synchronizing signals, each of the modules in the plurality then measuring said fault indicating parameter at times established by said time-synchronizing signals.
  - 18. The system of claim 17 wherein said time-synchronizing signals are transmitted as RF signals.
  - 19. The system of claim 17 wherein said time-synchronizing signals are transmitted using power line carrier injection.
  - 20. The system of claim 17 wherein said time-synchronizing signals are transmitted via fiber optic communication links.

21. A system for providing differential relay protection of a bus or primary substation power device through wireless sensing of current differential on at least one pair of electrical conductors carrying current to and from, respectively, said bus or primary substation power device, the system comprising:
- at least a pair of sensor modules, one of such sensor modules mounted upon each of the conductors in the at least one pair for measuring the current flowing through said conductor;
  
  wherein each sensor module includes;
  
  control and timing circuitry for causing all of said modules in the at least one pair to measure the analog current on its associated conductor simultaneously;
  
  a transmitter for transmitting signals from said modules commensurate with the current measured thereby;
  
  a master controller having;
  
  a receiver for receiving said signals;
  
  a processor for comparing said signals received from each of the modules on each of the conductors; and
  
  a processor to generate a substation control relay signal which is operated in response to a detected difference between said compared signals exceeding a predetermined threshold level to protect said bus or primary substation power device.

22. An integrated system for performing metering, monitoring and control functions at a high voltage power substation, power grid pole-top capacitor banks and auto-recloser switch locations, said system comprising:
- a plurality of individual sensor modules each of said sensor modules in the plurality being removeably mounted upon a high voltage AC power conductor at said substation, each of said modules including;
  
  sensing circuitry for simultaneously measuring each of a plurality of variable parameters, including voltage and current, power and reactive power associated with operation of said conductor upon which it is mounted;
  
  timing and control circuitry for GPS time-synchronizing the measurement of said parameters by said plurality of modules, whereby each of said modules measures the value of the same parameter at the same time on its associated conductor;
  
  a transmitter for transmitting signals commensurate with the values of said parameters measured by said modules;
  
  a Master Controller having;
  
  a receiver for receiving said signals from each of said sensor modules;
  
  a processor for processing said signals from each of said sensor modules and generating a set of digital signals in response thereto,a transmitter for sending said digital signals over a wide area communications network for performing metering, monitoring and control functions at corresponding sensor module locations.
- View Dependent Claims (23, 24, 25, 26)
- - 23. The integrated system of claim 22, wherein the Master Controller can also receive substation control/status and conditioning signals from existing current and potential transformers, process the values of said signals and generate a set of digital control signals in response thereto.
  - 24. The integrated system of claim 22 wherein said Master Controller is further comprised of alarm status monitoring circuitry, for detecting a fault status and performing select-before-operate control functions through interposing relays, or generating pulse control signals.
  - 25. The integrated system of claim 22 wherein said Master Controller further includes means for establishing whether each of the conductors of said first plurality is energized, and means for selecting an appropriate scale factor to be applied to a voltage reading from each of said sensor modules in accordance with the energized state of adjacent conductors determined by calibration at the time of installation.
  - 26. The integrated system of claim 22 wherein said Master Controller can transmit the voltage and reactive power at said power grid pole-top capacitor bank location for operator control over the wide area SCADA network.

27. A system for monitoring a plurality of parameters associated with each of a plurality of energized electrical power conductors of a power delivery network over the full operating range from minimum to maximum conductor current, said system comprising:
- a plurality of sensor modules for complete installation and removal while said conductors are energized, each one of said modules being mounted upon one of said energized electrical conductors;
  
  each of said sensor modules in the plurality having;
  
  circuitry for sensing and measuring values for any of a plurality of parameters of the associated power conductor upon which said sensor module is mounted;
  
  timing and control circuitry for synchronizing the measurements with GPS level timing accuracy such that each sensor module can measure any of the plurality of parameters at the same time;
  
  a processor for identifying, manipulating and processing said sensed and measured values in order to generate encoded signals;
  
  a transmitter for periodically transmitting time-synchronized sequences of said encoded signals in bursts of predetermined duration;
  
  means carried by each of said modules for controlling the starting times of said data bursts by said transmitting means using direct sequence code division spread spectrum multiple access 2-way communication links for simultaneous transmissions from multiple sensor modules;
  
  a remote master controller, remote from said modules, for receiving said encoded signals from each of said plurality of modules and decoding said signals to provide said sensed and measured parameter values in order to derive from said values operational status information, including normal, abnormal and transient operating conditions, about said power conductors, in order to synchronize control of said power delivery network over said full operating range during all of said normal, abnormal and transient operating conditions, in accordance with said operational status information.

28. A method of monitoring and controlling a power delivery network having a plurality of power conductors over the full operating range from minimum to maximum conductor current, said method comprising:
- removeably mounting a plurality of sensor modules upon the plurality of power conductors while said conductors are energized, each one of said modules being mounted upon one of said energized electrical conductors;
  
  using said plurality of sensor modules to sense and measure values for any of a plurality of parameters of the associated power conductor upon which said sensor module is mounted;
  
  synchronizing said sensing and measuring by each of the sensor modules in the plurality with GPS level timing accuracy such that each sensor module can measure any of the plurality of parameters at the same time;
  
  identifying, manipulating and processing said sensed and measured values in order to generate encoded signals;
  
  transmitting time-synchronized sequences of said encoded signals in bursts of predetermined duration using direct sequence code division spread spectrum multiple access 2-way communication links for simultaneous transmissions from multiple sensor modules;
  
  receiving said encoded signals from each of said plurality of modules and decoding said signals to provide said sensed and measured parameter values in order to derive from said values operational status information, including normal, abnormal and transient operating conditions, about said power conductors, in order to synchronize control of said power delivery network over said full operating range during all of said normal, abnormal and transient operating conditions, in accordance with said operational status information.

29. A high voltage conductor mounted sensor module provides metering grade high voltage, current, and phase angle measurement accuracy, remote customer meter reading gateway functions and comprises:
- a metallic housing mounted in surrounding relation to and conductively isolated from an associated high voltage conductor in a plurality of high voltage conductors, whereby a charging current is present on said housing due to the electric field of said associated high voltage conductor;
  
  charge current sampling circuitry for sensing voltage proportional to said charging current;
  
  conductor current sensing and sampling circuitry for measuring conductor current through said high voltage conductor;
  
  a processor for accurately determining voltage and current phase angles simultaneously using GPS time markers at the same point in time for both the sampled current and voltage, and determining power factor, real and reactive power, and frequency means for data concentration of meter reads from a cluster of customer meters for re-transmission ; and
  
  a transmitter for transmitting the measured values for said voltage, conductor current as well as the determined voltage and current phase angles, power factor, real and reactive power flow, frequency, and customer meter data from a cluster group to a Master Controller using secure direct sequence two-way Code Division Spread Spectrum Multiple Access Communications
- View Dependent Claims (30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43)
- - 30. The high voltage conductor mounted sensor module as in claim 29, wherein said current sampling circuitry for sensing the charging current is comprised of corona shielded, multiple series-parallel hub capacitors which are electrically coupled to the high voltage conductor.
  - 31. The high voltage conductor mounted sensor module as in claim 29 wherein the influence of adjacent conductors in the plurality, and stray capacitances, is accounted for through a calibration sensor module comprising:
    - an electronic switch for electrically coupling the current sampling and measurement circuitry to a known high voltage resistance to ground thereby bypassing the charging current from the multiple hub capacitors connected in parallel from flowing through said measurement circuitry;
      
      processing means for accurately calculating a voltage proportional to the resistive current measured by the current sampling and measurement circuitry when the switch is activated;
      
      wherein said processing means includes a scale factor responsive to energized or de-energized state of each of said adjacent conductors and determined during calibration.
  - 32. The high voltage conductor mounted sensor module as in claim 30, further comprisingan electronic switch for electrically coupling a fixed precision capacitor to said high voltage power conductor in order to measure the current through the precision capacitor while disconnecting the series-parallel hub capacitors from said high voltage power conductor, wherein a change in this precision capacitor current during operation allows dynamic calibration of the voltage sensing circuitry during temporary stray capacitance changes due to various factors.
  - 33. The high voltage conductor mounted sensor module as in claim 30 wherein said voltage and current sampling circuitry includes sensors which surround the high voltage conductor in separate planes to allow single hot stick conductor mounting without violating conductor clearances and allowing maximum hub capacitance in shielded area free from direct precipitation effects.
  - 34. The high voltage conductor mounted sensor module as in claim 30 further comprising GPS timing circuitry which allows for synchronized current and voltage measurements.
  - 35. The high voltage conductor mounted sensor module as in claim 30 wherein the transmitter is an RF communication link within a wide area communication network which utilizes code division spread spectrum multiple access around GPS time markers for hacker free RF communications between the sensor module and the Master Controller.
  - 36. The high voltage conductor mounted sensor module as in claim 30 further comprising:
    - a spherical video cam for taking a video snap shot of the pole switch prior to and after executing an open/close SCADA command; and
      
      a video processor for compressed video processing and transmission of said pole switch video snap shot.
  - 37. The high voltage conductor mounted sensor module as in claim 30 further comprising circuitry for determining the harmonic content and transient randomness of the harmonic content of voltage and current signals through the high voltage conductor for high impedance fault identification.
  - 38. The high voltage conductor mounted sensor module as in claim 30 further comprising environmental sensors for measuring the conductor temperature, ambient air temperature, relative humidity, wind speed and wind direction
  - 39. The high voltage conductor mounted sensor module as in claim 30 co-located at distribution voltage pole-top switches to detect faulted feeder sections, transmit such information through the Master Controller to allow a Control Center Operator to isolate the faulted segment and restore service to unfaulted sections within seconds.
  - 40. The high voltage conductor mounted sensor module as in claim 39, wherein said Master Controller receives the signals transmitted from the sensor module, processes said signals, and transmits GPS synchronizing command control signals back to the sensor module in order to control further operations of said sensor module.
  - 41. The high voltage conductor mounted sensor module as in claim 40, wherein said Master Controller receives data from a group of several customer meters for re-transmission via a USAT wide area communications network to a Customer Billing Center.
  - 42. The high voltage conductor mounted sensor module as in claim 41 wherein said Master Controller can download commands from the Control Center Operator via the USAT wide area network to said conductor mounted sensor for re-transmission to the customer meter for power demand control.
  - 43. The high voltage conductor mounted sensor module according to claim 42 that can compare total meter reading demand of the customer group in communication with it to detect interruption of service based on successive customer group meter reading scans.

44. A high voltage conductor mounted sensor for detecting earth quake vibrations, comprising:
- a metallic housing mounted in surrounding relation to and conductively isolated from the associated conductor, upon which it is mounted;
  
  a piezzo electric transducer for detecting conductor vibrations and representing them in the form of an electrical signal;
  
  memory for storing the electrical signal which represents said measured conductor vibrations as a dynamic record over pre-selectable intervals;
  
  processing means for calculating the magnitude and frequency of said electrical signal; and
  
  filtering means for digitally filtering out wind portions of said electrical signal which represent wind induced vibrations from earthquake induced vibrations by filtering out those portions of the signal which fall outside the earthquake frequency band.
- View Dependent Claims (45)
- - 45. The high voltage conductor mounted sensor of claim 44, further comprising:
    - a transmitter for transmitting the filtered electrical signal which represents detected earthquake induced vibrations to a Master Controller, wherein said Master Controller receives said transmitted signals in digital form and further transmits GPS synchronized multiple sensor module earth quake detection signals over a wide area communications network or USAT satellite network.

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Current Assignee
Roosevelt Fernandes
Original Assignee
Roosevelt Fernandes
Inventors
Fernandes, Roosevelt

Application Number

US11/527,093
Publication Number

US 20080077336A1
Time in Patent Office

Days
Field of Search
US Class Current

702/57
CPC Class Codes

G01R 15/06   having reactive components,...

G01R 15/142   Arrangements for simultaneo...

G01R 19/2513   Arrangements for monitoring...

H02H 1/0061   concerning transmission of ...

H02H 1/06   Arrangements for supplying ...

H02H 7/226   for wires or cables, e.g. h...

H02J 13/00002   characterised by monitoring

H02J 13/00006   characterised by informatio...

H02J 13/00007   using the power network as ...

H02J 13/00017   using optical fiber

H02J 13/00022   using wireless data transmi...

H02J 3/00125   Transmission line or load t...

H02J 50/10   using inductive coupling

H02J 7/34   Parallel operation in netwo...

H04Q 2209/40   using a wireless architecture

H04Q 2209/823   where the data is sent when...

H04Q 9/04   Arrangements for synchronou...

Y02E 60/00   Enabling technologies; Tech...

Y04S 10/30   State monitoring, e.g. faul...

Y04S 40/12   characterised by data trans...

Y04S 40/121 : using the power network as ...

Y04S 40/124 : using wired telecommunicati...

Y04S 40/126 : using wireless data transmi...

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Power line universal monitor

First Claim

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Abstract

562 Citations

45 Claims

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Power line universal monitor

First Claim

0 Assignments

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0 Petitions

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Accused Products

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Abstract

562 Citations

45 Claims

Specification

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Solutions

Use Cases

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