RU2001108386A - METHOD AND SYSTEM FOR MEASURING DEPENDING ON THE FREQUENCY OF ELECTRICAL PARAMETERS - Google Patents

Claims (43)

1. The method of measuring frequency-dependent electrical parameters using an electricity meter included in an electrical system having a variable frequency, characterized in that it includes the following operations: measuring the frequency of electricity; the choice of the reference waveform having a transition through the zero level in the positive direction; synchronization of two ideal waveforms with a specified reference waveform, each of these two ideal waveforms having an ideal frequency; obtaining the waveform of the input signal; and determining the signal value of the indicated ideal frequency within the specified waveform of the input signal, the two ideal waveforms being a function of the indicated frequency and phase-shifted relative to each other by approximately 90 ^° , while one ideal waveform displays the in-phase component and the other ideal waveform oscillation displays the quadrature component.  2. The method according to p. 1, characterized in that the operation of measuring the frequency of electricity includes the operation of determining the time interval between the set of samples of the waveform and counting the number of samples between the set of transitions through the zero level of the specified waveform.  3. The method according to p. 1, characterized in that it further includes the operation of determining the angle of the specified signal of ideal frequency, available inside the specified waveform of the input signal, relative to the specified reference waveform.  4. The method according to p. 1, characterized in that it further includes the following operations: multiplying the indicated waveform of the input signal by the specified in-phase ideal waveform, to obtain an in-phase product for each sample from a plurality of samples in the power supply network, at least for at least one power supply period; adding the specified in-phase product for each sample to the contents of the in-phase accumulating adder to obtain a common-mode summing value; multiplying the specified waveform of the input signal by the specified quadrature ideal waveform, to obtain a quadrature product for each sample from a plurality of samples in a power supply period, for a plurality of power supply periods; and adding said quadrature product for each sample to the contents of the quadrature accumulating adder to obtain a quadrature summing value.  5. The method according to p. 4, characterized in that it further includes the operation of determining the in-phase physical quantity and the quadrature physical quantity.  6. The method according to p. 5, characterized in that it further includes the operation of counting the number of samples on the specified set of periods of the supply network, to determine the number of samples, and the specified in-phase physical quantity is equal to the specified in-phase summing value divided by the specified number of samples, and said quadrature physical quantity is equal to said quadrature summing value divided by said number of samples.  7. The method according to p. 5, characterized in that the value and angle of the specified signal of ideal frequency within the specified waveform of the input signal depend on the in-phase physical quantity and the quadrature physical quantity.  8. The method according to p. 7, characterized in that it further includes the operation of determining the value of the specified signal of ideal frequency by extracting the square root of the sum of the squares of the indicated in-phase and quadrature physical quantities, multiplied by a scaling factor, which is a function of the RMS value of one of ideal forms of vibration.  9. The method according to p. 7, characterized in that the operation of determining the specified angle is the determination of the specified angle in accordance with the table (see graphic part). 10. A system for measuring frequency-dependent electrical parameters using an electricity meter included in an electrical system having a variable frequency, characterized in that it includes the following means: means for measuring the frequency of electricity; means for selecting a reference waveform having a transition through a zero level in a positive direction; means for synchronizing two ideal waveforms with a specified reference waveform, each of these two ideal waveforms having an ideal frequency; means for generating a waveform of the input signal; and means for determining the signal value of the indicated ideal frequency within the specified waveform of the input signal, the two ideal waveforms being a function of the specified frequency and phase-shifted relative to each other by approximately 90 ^o , while one ideal waveform displays the in-phase component and the other ideal the waveform displays the quadrature component.  11. The system according to p. 10, characterized in that the said means of measuring the frequency of the electric power include means for determining the time interval between the plurality of samples of the waveform and counting the number of samples between the plurality of transitions through the zero level by the indicated waveform.  12. The system according to p. 10, characterized in that it further includes means for determining the angle of the specified signal of ideal frequency present inside the specified waveform of the input signal relative to the specified reference waveform.  13. The system according to p. 10, characterized in that it further includes means for multiplying the specified waveform of the input signal by the specified in-phase ideal waveform, to obtain an in-phase product for each sample from a plurality of samples in the period of the power supply network, at least for one period of the power supply network; means for adding said in-phase product for each sample to the contents of the in-phase accumulating adder to obtain a common-mode summing value; means for multiplying the specified waveform of the input signal with the specified quadrature ideal waveform, to obtain a quadrature product for each sample from a plurality of samples in the period of the power supply network, for many periods of the power supply network; and means for adding said quadrature product for each sample to the contents of the quadrature accumulating adder to obtain a quadrature summing value.  14. The system according to p. 13, characterized in that it further includes means for determining the in-phase physical quantity and the quadrature physical quantity.  15. The system according to p. 14, characterized in that it further includes means for counting the number of samples on the specified set of periods of the power supply network, to determine the number of samples, and the specified in-phase physical quantity is equal to the specified in-phase summing value divided by the specified number of samples and said quadrature physical quantity is equal to said quadrature summing value divided by said number of samples.  16. The system according to p. 14, characterized in that the value and angle of the specified signal of ideal frequency within the specified waveform of the input signal depend on the indicated in-phase physical quantity and quadrature physical quantity.  17. The system according to p. 16, characterized in that it further includes means for determining the indicated signal value of the ideal frequency by extracting the square root of the sum of the squares of the indicated in-phase and quadrature physical quantities multiplied by a scaling factor, which is a function of the RMS value of one from ideal forms of oscillation.  18. The system according to p. 16, characterized in that the means for determining the specified angle are means for determining the specified angle in accordance with the table (see graphical part). 19. A device, characterized in that it includes a memory device for storing software for measuring frequency-dependent electrical parameters using an electricity meter included in an electrical system having a variable frequency, wherein said software performs the following operations: frequency measurement electricity; the choice of the reference waveform having a transition through the zero level in the positive direction; synchronization of two ideal waveforms with a specified reference waveform, each of these two ideal waveforms having an ideal frequency; obtaining the waveform of the input signal; and determining the signal value of the indicated ideal frequency within the specified waveform of the input signal, the two ideal waveforms being a function of the indicated frequency and phase-shifted relative to each other by approximately 90 ^° , while one ideal waveform displays the in-phase component and the other ideal waveform oscillation displays the quadrature component.  20. The device according to p. 19, characterized in that the said software additionally performs the operations of determining the time interval between the set of samples of the waveform and counting the number of samples between the set of transitions through the zero level of the specified waveform.  21. The device according to p. 19, characterized in that the said software additionally carries out the operation of determining the angle of the specified signal of ideal frequency available inside the specified waveform of the input signal relative to the specified reference waveform.  22. The device according to p. 19, characterized in that the said software additionally performs the following operations: multiplying the specified waveform of the input signal by the specified common-mode ideal waveform to obtain an in-phase product for each sample from a plurality of samples in the period of the power supply network, at least for at least one power supply period; adding the specified in-phase product for each sample to the contents of the in-phase accumulating adder to obtain a common-mode summing value; multiplying the specified waveform of the input signal by the specified quadrature ideal waveform, to obtain a quadrature product for each sample from a plurality of samples in a power supply period, for a plurality of power supply periods; and adding said quadrature product for each sample to the contents of the quadrature accumulating adder to obtain a quadrature summing value.  23. The device according to p. 22, characterized in that the said software additionally carries out the operation of determining in-phase physical quantity and quadrature physical quantity.  24. The device according to p. 23, characterized in that the said software additionally carries out the operation of counting the number of samples on the specified set of periods of the power network, to determine the number of samples, and the specified in-phase physical quantity is equal to the specified in-phase summing value divided by the specified number of samples, and said quadrature physical quantity is equal to said quadrature summing value divided by said number of samples.  25. The device according to p. 23, characterized in that the value and angle of the specified signal of ideal frequency, available inside the specified waveform of the input signal, depend on the specified in-phase physical quantity and quadrature physical quantity.  26. The device according to p. 25, characterized in that the said software additionally performs the operation of determining the specified signal value of the ideal frequency by extracting the square root of the sum of the squares of the indicated in-phase and quadrature physical quantities, multiplied by a scaling factor, which is a function of the RMS value of one of ideal forms of vibrations.  27. The device according to p. 25, characterized in that the said software determines the specified angle in accordance with the table (see graphic part). 28. The method of measuring frequency-dependent electrical parameters using an electricity meter included in an electrical system having a variable frequency, characterized in that it includes the following operations: selecting a reference waveform having a transition through the zero level in the positive direction; synchronization of two ideal waveforms with a specified reference waveform, each of these two ideal waveforms having an ideal frequency; obtaining the waveform of the input signal; and determining the signal value of the indicated ideal frequency within the indicated waveform of the input signal, wherein said two ideal waveforms are phase-shifted approximately 90 ^° relative to each other, while one ideal waveform represents the in-phase component, and the other ideal waveform displays the quadrature component.  29. The method according to p. 28, characterized in that it further includes the operation of determining the angle of the specified signal of ideal frequency, available inside the specified waveform of the input signal relative to the specified reference waveform.  30. The method according to p. 28, characterized in that it further includes the following operations: multiplying the specified waveform of the input signal by the specified in-phase ideal waveform, to obtain an in-phase product for each sample from a plurality of samples in the period of the power supply network, at least for at least one power supply period; adding the specified in-phase product for each sample to the contents of the in-phase accumulating adder to obtain a common-mode summing value; multiplying the specified waveform of the input signal by the specified quadrature ideal waveform, to obtain a quadrature product for each sample from a plurality of samples in a power supply period, for a plurality of power supply periods; and adding said quadrature product for each sample to the contents of the quadrature accumulating adder to obtain a quadrature summing value.  31. The method according to p. 30, characterized in that it further includes the operation of determining a common-mode physical quantity and a quadrature physical quantity.  32. The method according to p. 31, characterized in that it further includes the operation of counting the number of samples on the specified set of periods of the power network, to determine the number of samples, and the specified in-phase physical quantity is equal to the specified in-phase summing value divided by the specified number of samples, and said quadrature physical quantity is equal to said quadrature summing value divided by said number of samples.  33. The method according to p. 31, characterized in that the value and angle of the specified signal of ideal frequency within the specified waveform of the input signal depend on the in-phase physical quantity and the quadrature physical quantity.  34. The method according to p. 33, characterized in that it further includes the operation of determining the value of the specified signal of ideal frequency by extracting the square root of the sum of the squares of the indicated in-phase and quadrature physical quantities, multiplied by a scaling factor, which is a function of the RMS value of one of ideal forms of vibration.  35. The method according to p. 33, characterized in that the operation of determining the specified angle is the determination of the specified angle in accordance with the table (see graphic part). 36. A system for measuring frequency-dependent electrical parameters using an electricity meter included in an electrical system having a variable frequency, characterized in that it includes the following means: means for selecting a reference waveform having a transition through the zero level in the positive direction; means for synchronizing two ideal waveforms with a specified reference waveform, each of these two ideal waveforms having an ideal frequency; means for generating a waveform of the input signal; and means for determining the signal value of the indicated ideal frequency within the specified waveform of the input signal, wherein the two ideal waveforms are phase-shifted approximately 90 ^° relative to each other, while one ideal waveform displays the in-phase component and the other ideal waveform displays the quadrature component .  37. The system according to p. 36, characterized in that it further includes means for determining the angle of the specified signal of ideal frequency, available inside the specified waveform of the input signal relative to the specified reference waveform.  38. The system according to p. 36, characterized in that it further includes the following means: means for multiplying the specified waveform of the input signal by the specified in-phase ideal waveform, to obtain an in-phase product for each sample from a plurality of samples in the period of the power supply network, for at least one period of the power supply network; means for adding said in-phase product for each sample to the contents of the in-phase accumulating adder to obtain a common-mode summing value; means for multiplying the indicated waveform of the input signal to the specified quadrature ideal waveform, to obtain a quadrature product for each sample from a plurality of samples in a power supply period, for a plurality of power supply periods; and means for adding said quadrature product for each sample to the contents of the quadrature accumulating adder to obtain a quadrature summing value.  39. The system of claim 38, wherein it further includes means for determining a common-mode physical quantity and a quadrature physical quantity.  40. The system according to p. 39, characterized in that it further includes means for counting the number of samples on the specified set of periods of the power supply network, to determine the number of samples, and the specified in-phase physical quantity is equal to the specified in-phase summing value divided by the specified number of samples and said quadrature physical quantity is equal to said quadrature summing value divided by said number of samples.  41. The system according to p. 39, characterized in that the value and angle of the specified signal of ideal frequency within the specified waveform of the input signal depend on the in-phase physical quantity and the quadrature physical quantity.  42. The system according to p. 41, characterized in that it further includes means for determining the indicated value of the ideal frequency signal by extracting the square root of the sum of the squares of the indicated in-phase and quadrature physical quantities, multiplied by a scaling factor, which is a function of the RMS value of one from ideal forms of oscillation.  43. The system according to p. 41, characterized in that the means for determining the specified angle are means for determining the specified angle in accordance with the table (see graphic part).

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