US2008281540A1PendingUtilityA1

Apparatus and method for estimating synchronized phasors at predetermined times referenced to a common time standard in an electrical system

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Assignee: ZWEIGLE GREGARY CPriority: Oct 18, 2005Filed: May 5, 2008Published: Nov 13, 2008
Est. expiryOct 18, 2025(expired)· nominal 20-yr term from priority
Y02E40/70Y04S10/22G01R 19/2513Y04S10/00Y02E60/00
55
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Claims

Abstract

An apparatus and method estimates a plurality of synchronized phasors at predetermined times referenced to an absolute time standard in an electrical power system. The method includes acquiring and determining a frequency of a power system signal, sampling the power system signal at a sampling interval rate based on a frequency of the power system signal to form signal samples, and generating a plurality of acquisition time values based on an occurrence of each of the signal samples at a corresponding plurality of different times referenced to the absolute time standard. The method further includes adjusting a phasor of each of the signal samples based on a time difference between a corresponding selected acquisition time value and a predetermined time referenced to an absolute time standard to form the plurality of synchronized phasors.

Claims

exact text as granted — not AI-modified
1 - 61 . (canceled) 
   
   
       62 . An apparatus for estimating a plurality of synchronized phasors at predetermined times referenced to a common time standard in an electrical power system, the apparatus comprising:
 a sampling means configured to sample a power system signal at a selected sampling interval rate to form a plurality of signal samples;   a time controller configured to generate a plurality of acquisition time values based on an occurrence of each of the plurality signal samples at a corresponding plurality of sample times referenced to the common time standard, each of the plurality of acquisition time values associated with a phasor magnitude and a phasor phase angle of each of the plurality of signal samples; and   a phasor estimator configured to adjust the phasor magnitude and the phasor phase angle for each of the plurality of signal samples based on a time difference between a corresponding selected acquisition time value of the plurality of acquisition time values and a predetermined time of the predetermined times referenced to the common time standard to form the plurality of synchronized phasors.   
   
   
       63 . The apparatus of  claim 62  further comprising a sample controller configured to determine the selected sampling interval rate. 
   
   
       64 . The apparatus of  claim 62  wherein the selected sampling interval rate is a frequency of a power system signal acquired at a location of the electrical power system. 
   
   
       65 . The apparatus of  claim 62  wherein the selected sampling interval rate is based on a fixed interval. 
   
   
       66 . The apparatus of  claim 62  wherein the common time standard is an absolute time standard. 
   
   
       67 . The apparatus of  claim 62 , wherein each of the plurality of synchronized phasors comprises a corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles. 
   
   
       68 . The apparatus of  claim 67 , wherein the phasor estimator is further configured to:
 interpolate each of the plurality of phasor magnitudes to form each of the plurality of referenced phasor magnitudes; and   rotate each of the plurality of phasor phase angles to form each of the plurality of referenced phasor phase angles.   
   
   
       69 . The apparatus of  claim 67 , further comprising a digital filter to generate a plurality of filtered signals, wherein the phasor estimator is further configured to phase shift each of the plurality of filtered signals by 90 degrees and interpolate prior to calculating reference phasor magnitudes and referenced phasor phase angles. 
   
   
       70 . The apparatus of  claim 67 , further comprising a phasor calculator configured to calculate an uncalibrated referenced phasor magnitude and a prealigned referenced phasor phase angle of each of the plurality of signal samples at the plurality of acquisition time values prior to adjusting the phasor magnitude and the phasor phase angle to the corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles. 
   
   
       71 . The apparatus of  claim 62 , wherein the time difference comprises a difference in time between an occurrence of a preceding selected acquisition time value of the plurality of acquisition time values and a predetermined time of the predetermined times referenced to the common time standard. 
   
   
       72 . The apparatus of  claim 62 , wherein the time difference comprises a difference in time between an occurrence of a predetermined time of the predetermined times referenced to the common time standard and a next selected acquisition time value of the plurality of acquisition time values. 
   
   
       73 . The apparatus of  claim 62 , wherein the predetermined times are synchronized across the electrical power system. 
   
   
       74 . The apparatus of  claim 62 , wherein the predetermined times are determined local to the apparatus. 
   
   
       75 . The apparatus of  claim 62 , wherein the phasor estimator is further configured to phase align each of the plurality of synchronized phasors to a reference phasor with a predetermined phase and frequency. 
   
   
       76 . The apparatus of  claim 75 , wherein the predetermined frequency comprises 60 Hz. 
   
   
       77 . The apparatus of  claim 75 , wherein the predetermined frequency comprises 50 Hz. 
   
   
       78 . The apparatus of  claim 62 , wherein the power system signal comprises a plurality of power system signals. 
   
   
       79 . The apparatus of  claim 62 , further comprising an analog filter configured to filter the power system signal prior to receipt by the sampling means. 
   
   
       80 . The apparatus of  claim 62 , wherein the common time standard is based on a global positioning system signal communicated via an IRIG timecode protocol. 
   
   
       81 . The apparatus of  claim 62 , further comprising a digital filter configured to digitally filter each of the plurality of signal samples. 
   
   
       82 . The apparatus of  claim 64 , wherein the sampling interval rate is an integer multiple of the frequency of the power system signal. 
   
   
       83 . The apparatus of  claim 62 , further comprising utilizing one or more of the plurality of synchronized phasors to perform a power system function selected from the group consisting of: protection; automation; metering; control; and combinations thereof. 
   
   
       84 . The apparatus of  claim 63 , wherein the sample controller is further configured to generate a sample frequency signal based on the selected sampling interval rate, the sample frequency signal aligned with the plurality of acquisition time values and utilized to form the plurality of synchronized phasors. 
   
   
       85 . The apparatus of  claim 67 , wherein the phasor estimator is further configured to:
 remove implementation magnitude distortion from the sample signal prior to forming each of the plurality of synchronized phasors; and   remove implementation phase angle distortion from the sample signal prior to forming each of the plurality of synchronized phasors.   
   
   
       86 . The apparatus of  claim 62 , wherein the location of the power system signal is local and the power system signal comprises a local analog input signal. 
   
   
       87 . The apparatus of  claim 62 , wherein the location of the power system signal is remote and the power system signal comprises a digitized remote analog input signal. 
   
   
       88 . The apparatus of  claim 62 , wherein each of the plurality of synchronized phasors comprises a corresponding plurality of referenced phasor sequence quantities. 
   
   
       89 . A method for estimating a plurality of synchronized phasors at predetermined times referenced to a common time standard in an electrical power system, the method comprising:
 sampling a power system signal at a sampling interval rate to form a plurality of signal samples;   generating a plurality of acquisition time values based on an occurrence of each of the plurality signal samples at a corresponding plurality of sample times referenced to the common time standard, each of the plurality of acquisition time values associated with a phasor magnitude and a phasor phase angle of each of the plurality of signal samples; and   for each of the plurality of signal samples, adjusting the phasor magnitude and the phasor phase angle based on a time difference between a corresponding selected acquisition time value of the plurality of acquisition time values and a predetermined time of the predetermined times referenced to the common time standard to form the plurality of synchronized phasors.   
   
   
       90 . The method of  claim 89  further comprising the step of determining the frequency at a location on the power system before the sampling step such that the sampling interval rate is based on the frequency of the power system. 
   
   
       91 . The method of  claim 89  wherein the sampling interval rate is based on a fixed sampling rate. 
   
   
       92 . The method of  claim 89  wherein the common time standard comprises an absolute time standard. 
   
   
       93 . The method of  claim 89 , wherein each of the plurality of synchronized phasors comprises a corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles. 
   
   
       94 . The method of  claim 93 , further comprising interpolating each of the plurality of phasor magnitudes to form each of the plurality of referenced phasor magnitudes. 
   
   
       95 . The method of  claim 93 , further comprising the steps of filtering to generate a plurality of filtered signals; phase shifting each of the plurality of filtered signals by 90 degrees;
 interpolating; and calculating reference phasor magnitudes and referenced phasor angles.   
   
   
       96 . The method of  claim 93 , further comprising the step of calculating an uncalibrated referenced phasor magnitude and a prealigned phasor phase angle of each of the plurality of signal samples at the plurality of acquisition time values prior to adjusting the phasor magnitude and the phasor phase angle to the corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles. 
   
   
       97 . The method of  claim 93 , further comprising rotating each of the plurality of phasor phase angles to form each of the plurality of referenced phasor phase angles. 
   
   
       98 . The method of  claim 93 , further comprising calculating the phasor magnitude and phasor phase angle of each of the plurality of signal samples at the plurality of acquisition time values prior to adjusting the phasor magnitude and the phasor phase angle of each of the plurality of signal samples to the corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles. 
   
   
       99 . The method of  claim 89 , wherein the time difference comprises a difference in time between an occurrence of a preceding selected acquisition time value of the plurality of acquisition time values and a predetermined time of the predetermined times referenced to the common time standard. 
   
   
       100 . The method of  claim 89 , wherein the time difference comprises a difference in time between an occurrence of a predetermined time of the predetermined times referenced to the common time standard and a next selected acquisition time value of the plurality of acquisition time values. 
   
   
       101 . The method of  claim 89 , wherein the predetermined times are synchronized across the electrical power system. 
   
   
       102 . The method of  claim 89 , wherein the predetermined times are determined at a location on the electrical power system local to the step of determining a frequency of the power system is performed. 
   
   
       103 . The method of  claim 89 , further comprising phase aligning each of the plurality of synchronized phasors to a reference phasor with predetermined phase and frequency. 
   
   
       104 . The method of  claim 103 , wherein the predetermined frequency comprises 60 Hz. 
   
   
       105 . The method of  claim 103 , wherein the predetermined frequency comprises 50 Hz. 
   
   
       106 . The method of  claim 89 , wherein the power system signal comprises a plurality of power system signals. 
   
   
       107 . The method of  claim 89 , further comprising analog filtering the power system signal prior to the step of sampling. 
   
   
       108 . The method of  claim 89 , wherein the common time standard is based on a global positioning system signal communicated via an IRIG timecode protocol. 
   
   
       109 . The method of  claim 89 , further comprising digitally filtering each of the plurality of signal samples. 
   
   
       110 . The method of  claim 90 , wherein the sampling interval rate is an integer multiple of the frequency of the power system signal. 
   
   
       111 . The method of  claim 89 , further comprising utilizing one or more of the plurality of synchronized phasors to perform a power system function selected from the group consisting of: protection, automation, metering, control, and combinations thereof. 
   
   
       112 . The method of  claim 90 , further comprising generating a sample frequency signal based on the sampling interval rate, the sample frequency signal aligned with the plurality of acquisition time values and utilized to form the plurality of synchronized phasors. 
   
   
       113 . The method of  claim 89 , further comprising removing implementation magnitude distortion from the sample signal prior to forming each of the plurality of synchronized phasors. 
   
   
       114 . The method of  claim 113 , further comprising removing implementation phase angle distortion from the sample signal prior to forming each of the plurality of synchronized phasors. 
   
   
       115 . The method of  claim 89 , wherein the power system signal comprises a local analog input signal. 
   
   
       116 . The method of  claim 89 , wherein the power system signal comprises a digitized remote analog input signal. 
   
   
       117 . The method of  claim 89 , wherein each of the plurality of synchronized phasors comprises a corresponding plurality of referenced phasor sequence quantities. 
   
   
       118 . A method for estimating a plurality of synchronized phasors at predetermined times referenced to a common time standard in an electrical power system, the method comprising:
 sampling a power system signal at a selected sampling interval rate to form a plurality of signal samples;   generating a plurality of acquisition time values based on an occurrence of each of the plurality signal samples at a corresponding plurality of different times referenced to the common time standard, each of the plurality of acquisition time values associated with a phasor magnitude and a phasor phase angle of each of the plurality of signal samples; and   for each of the plurality of signal samples, interpolating the phasor magnitude and rotating phasor phase angle to form a corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles of the plurality of synchronized phasors based on a time difference between a corresponding selected acquisition time value of the plurality of acquisition time values and a predetermined time of the predetermined times referenced to the common time standard.   
   
   
       119 . The method of  claim 118 , further comprising the step of determining the frequency at a location of the power system before the sampling step such that the sampling interval rate is based on the frequency of the power system. 
   
   
       120 . The method of  claim 118  wherein the sampling interval rate is based on a fixed sampling rate. 
   
   
       121 . The method of  claim 118  wherein the common time standard is an absolute time standard. 
   
   
       122 . The method of  claim 118 , further comprising calculating the phasor magnitude and phasor phase angle of each of the plurality of signal samples at the plurality of acquisition time values prior to adjusting the phasor magnitude and the phasor phase angle of each of the plurality of signal samples to the corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles. 
   
   
       123 . The method of  claim 118 , wherein the rotating phasor phase angle comprises a rotation of 90 degrees. 
   
   
       124 . The method of  claim 118 , further comprising the step of calculating an uncalibrated referenced phasor magnitude and a prealigned phasor phase angle of each of the plurality of signal samples at the plurality of acquisition time values prior to adjusting the phasor magnitude and the phasor phase angle to the corresponding plurality of referenced phasor magnitudes and referenced phasor phase angles. 
   
   
       125 . The method of  claim 118 , wherein the time difference comprises a difference in time between an occurrence of a preceding selected acquisition time value of the plurality of acquisition time values and a predetermined time of the predetermined times referenced to the common time standard. 
   
   
       126 . The method of  claim 118  wherein the time difference comprises a difference in time between an occurrence of a predetermined time of the predetermined times referenced to the common time standard and a next selected acquisition time value of the plurality of acquisition time values. 
   
   
       127 . The method of  claim 119 , wherein each of the plurality of synchronized phasors is further phase aligned to a reference phasor with predetermined phase and frequency. 
   
   
       128 . The method of  claim 127 , wherein the predetermined frequency comprises 60 Hz. 
   
   
       129 . The method of  claim 127 , wherein the predetermined frequency comprises 50 Hz. 
   
   
       130 . The method of  claim 118 , wherein the common time standard is based on a global positioning system signal communicated via an IRIG timecode protocol. 
   
   
       131 . The method of  claim 118 , wherein each of the plurality of synchronized phasors comprises a corresponding plurality of referenced phasor sequence quantities. 
   
   
       132 . The method of  claim 118 , wherein the power system signal comprises a digitized remote analog input signal. 
   
   
       133 . The method of  claim 118 , wherein the power system signal comprises a local analog input signal.

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