Synchronous vector measuring device
First Claim
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1. A synchronous vector measuring device comprising:
- a voltage measuring part that measures the voltage of an electric power system in a period equal to 1/4N (N being a positive integer) of one period of a reference wave;
a voltage root-mean-square value calculation part that calculates, at each of timings at which said voltage is measured, a voltage root-mean-square value at a specific timing from said voltages measured at past 4N timings including said specific timing; and
an absolute phase angle calculation part that calculates an absolute phase angle of a synchronous vector at each of said timings according to the following expression (where β
is the absolute phase angle, vre is the voltage measured at the specific timing, and V is the voltage root-mean-square value calculated at the specific timing).
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Abstract
A synchronous vector measuring device can measure an absolute phase angle of a synchronous vector excellent in continuous numerical stability at high speed and with high accuracy in a noisy electric power system. A voltage measuring part measures the voltage of the electric power system at a period equal to 1/4N (N being a positive integer) of one period of a reference wave. A voltage root-mean-square value calculation part calculates, at each voltage measuring timing, a voltage root-mean-square value at a specific timing from the voltages measured at past 4N timings including the specific timing. An absolute phase angle calculation part makes, at each voltage measuring timing, an inverse cosine of a value obtained by dividing the voltage measured at the specific timing by the product of the voltage root-mean-square value and the square root of 2, as the absolute phase angle of the synchronous vector at the specific timing.
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Citations
4 Claims
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1. A synchronous vector measuring device comprising:
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a voltage measuring part that measures the voltage of an electric power system in a period equal to 1/4N (N being a positive integer) of one period of a reference wave;
a voltage root-mean-square value calculation part that calculates, at each of timings at which said voltage is measured, a voltage root-mean-square value at a specific timing from said voltages measured at past 4N timings including said specific timing; and
an absolute phase angle calculation part that calculates an absolute phase angle of a synchronous vector at each of said timings according to the following expression (where β
is the absolute phase angle, vre is the voltage measured at the specific timing, and V is the voltage root-mean-square value calculated at the specific timing). - View Dependent Claims (4)
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2. A synchronous vector measuring device comprising:
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a voltage measuring part that measures the voltage of an electric power system in a period equal to 1/4N (N being a positive integer) of one period of a reference wave;
a voltage root-mean-square value calculation part that calculates, at each of timings at which said voltage is measured, a voltage root-mean-square value at a specific timing from said voltages measured at past 4N timings including said specific timing;
a voltage root-mean-square value averaging part that makes, at each of said timings, an average value between one of said voltage root-mean-square values calculated at said specific timing and at least another one of said voltage root-mean-square values calculated at at least one timing preceding said specific timing to be as a voltage root-mean-square value average value at said specific timing; and
an absolute phase angle calculation part that calculates an absolute phase angle of a synchronous vector at each of said timings according to the following expression (where β
is the absolute phase angle, vre is the voltage measured at the specific timing, and Vave is the voltage root-mean-square value average value calculated at the specific timing).
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3. A synchronous vector measuring device comprising:
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a voltage measuring part that measures the voltage of an electric power system in a period equal to 1/4N (N being a positive integer) of one period of a reference wave;
a voltage root-mean-square value calculation part that calculates, at each of timings at which said voltage is measured, a voltage root-mean-square value at a specific timing from said voltages measured at past 4N timings including said specific timing;
a voltage root-mean-square value averaging part that makes, at each of said timings, an average value between one of said voltage root-mean-square values calculated at said specific timing and at least another one of said voltage root-mean-square values calculated at at least one timing preceding said specific timing to be as a voltage root-mean-square value average value at said specific timing;
a chord length calculation part that calculates, at each of said timings, a voltage rotating vector directed to a point represented by a complex number on a complex plane consisting of a real part which is one of said voltages measured at said specific timing, and an imaginary part which is one of said voltages measured at a timing delayed by 90 electrical degrees from said specific timing, and further calculates the length of a cord connecting between a tip end of one of said voltage rotating vectors calculated at said specific timing and a tip end of another one of said voltage rotating vectors calculated at a timing immediately preceding said specific timing;
a rotational phase angle calculation part that adds, at each of said timings, said chord lengths calculated at the past 4N timings including said specific timing, and calculates, based on a total sum of said cord lengths and said voltage root-mean-square value average value, a phase angle between one of said voltage rotating vectors calculated at said specific timing and another one of said voltage rotating vectors calculated at a timing preceding said specific timing by one period of said reference wave;
a frequency calculation part that calculates, at each of said timings, the frequency of said electric power system from said phase angle thus calculated;
a voltage instantaneous value estimating part that calculates, at each of said timings, an angular velocity of a voltage rotating vector from said frequency calculated at said specific timing, and expands each of said voltages measured at the past 4N timings including said specific timing according to the following expression
vre=P1 cos ω
t+P2 sin ω
t(where vre is each of the voltages measured at the past 4N timings including the specific timing, ω
is the angular velocity of a voltage rotating vector obtained at the specific timing, and P1 and P2 are coefficients at the specific timing), calculates coefficient estimated values at said specific timing from said coefficients at the past 4N timings including said specific timing by using a least square method, and estimates a voltage real number instantaneous estimated value at said specific timing from said coefficient estimated values according to the following expression
vre— est=P1est cos ω
t+P2est sin ω
t(where vre — est is the voltage real number instantaneous estimated value estimated at said specific timing, and P1est and P2est are the coefficient estimated values estimated at said specific timing); and
a absolute phase angle calculation part that calculates an absolute phase angle of the synchronous vector at each of said timings according to the following expression (where β
is the absolute phase angle, vre— est is the voltage real number instantaneous estimated value estimated at said specific timing, and Vave is the voltage root-mean-square value average value calculated at said specific timing).
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Specification
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Current AssigneeMitsubishi Denki Kabushiki Kaisha (Mitsubishi Electric Corporation)
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Original AssigneeTmt&D Corporation
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InventorsSeki, Kempei
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Granted Patent
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Time in Patent OfficeDays
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Field of Search
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US Class Current324/76.390
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CPC Class CodesG01R 21/133 by using digital technique
