RU99122161A - DEVICE FOR COMPARING TWO SIGNALS, DEVICE AND METHOD FOR FORMING NON-STATIONARY SIGNALS - Google Patents

Claims (23)

1. Device for real-time comparison of two signals (S1 (t), S2 (t)), each of which is represented by magnitude and phase, characterized in that it contains a sampling tool for obtaining a set of samples of each of two signals representing the values of each of two signals, at least at two different points in time, and computing means for calculating the value of M _{k + 1} corresponding to the phase difference of the two signals based on samples. 2. The device according to claim 1, characterized in that the sampling means allocates a sample (S1 _k ) representing the value of the first of these signals at the first moment of time, selects a sample (S2 _k ) representing the value of the second of these signals at the same first moment time; extracts a sample (S1 _{k + 1} ) representing the magnitude of the first of these signals at the second moment in time, and extracts a reference (S2 _k-1 ) representing the magnitude of the second of these signals at the same second moment in time. 3. The device according to claim 2, characterized in that the computing means includes means for obtaining the derived values B1 _k , B2 _k , B1 _{k + 1} and B2 _{k + 1} from samples S1 _k , S2 _k , S2 _{k + 1} multiplying means for multiplying the values of B1 _k by B2 _{k + 1} and multiplying the values of B2 _k by B1 _{k + 1} to obtain the first product B1 _k B2 _{k + 1} and the second product B2 _k B1 _{k + 1} ; and summing means for adding the first and second products to obtain a calculation result (M _{k + 1} ) corresponding to the phase difference between the first and second complex vector quantities. 4. The device according to claim 3, characterized in that the values of B1 _k and B2 _k are found using the following relationships:
B1 _k = FK2 [S1 _k + S1 _k-1 FK1 B1 _k-1 ]
B2 _k = FK2 [S2 _k + S2 _k-1 FK1 B2 _k-1 ]
in which FK1 and FK2 are constants corresponding to the given equations. 5. The device according to claim 4, characterized in that the constants FK1 and FK2 are determined by the following relationships:

where RB and LB are constants. 6. The device according to claim 2, characterized in that the samples S1 _k and S2 _k are obtained by sampling the voltage or current in the transmission line.  7. The device according to claim 6, characterized in that the signals S1 (t) and S2 (t) are voltages or currents that change according to a sinusoidal law, or a combination of voltages and currents. 8. The device according to claim 6, characterized in that it also contains means for using the obtained calculation result M _{k + 1} to determine the presence of damage in the specified transmission line.  9. The device according to p. 8, characterized in that the obtained calculation result is used to detect interphase failure in a three-phase transmission line system; and samples S1 (t) and S2 (t) are obtained from interphase voltages and complex currents.  10. The device according to claim 8, characterized in that the obtained calculation result is used to detect a phase-to-ground failure in a three-phase transmission line system; a S1 (t) and S2 (t) are obtained from phase-ground voltages and complex currents. 11. The device according to claim 6, characterized in that it further comprises means for using the obtained calculation result M _{k + 1} to determine the direction of the power flow in the transmission line.  12. The device according to claim 11, characterized in that, together with a filter of symmetrical components, the output sequences of the components of the specified filter are the input signals of the device. 13. The device according to p. 6, characterized in that it further comprises means for subtracting a given constant (MS) from the obtained calculation result M _{k + 1} and using the difference M _{k + 1} - MS to obtain a signal (θ _{k + 1} ) that determines energy contained in the difference signal S1 (t) -S2 (t). 14. The device according to p. 6, characterized in that it further comprises means for using the obtained calculation result M _{k + 1} in order to determine whether or not the voltage or current in the transmission line exceeds a predetermined threshold level. 15. The device according to claim 2, characterized in that it further comprises a scaling means for converting the obtained calculation result (M _{k + 1} ), the scaling means multiplying the result by a predetermined factor proportional to the sampling period.  16. A method for generating non-stationary signals of positive symmetric sequences of components (I1) and negative symmetric sequences of components (I2) of currents of a power supply system, including obtaining samples of these currents of a power supply system and using digital logic circuits to obtain digital values of symmetric components (I1, I2) in real time, characterized in that the digital logic circuits include systems of delay elements, amplifying elements and summing elements connected in working condition for the formation of digital symmetric components in real time, with digital logic circuits forming symmetric components proportional to I1k and I2k, I1 represents the current of the positive sequence, I2 represents the current of the negative sequence, the subscript k refers to the digital samples of the corresponding components. 17. The method according to p. 16, characterized in that the digital logic circuits form Clark's components:

wherein said power supply system includes a first phase (phase-a), a second phase (phase-b) and a third phase (phase-c), where Ia is the current in phase-a, Ib is the current in phase-b and Ic is a current in phase s. 18. The method according to p. 17, characterized in that the digital logic circuits receive samples Ia, Ib and IC; form the quantities Iα _k , Iα _k-1 , Iβ _k and Iβ _k-1 ; and then make combinations of the quantities Ια _k , Iα _k-1 , Iβ _k and Iβ _k-1 to obtain the values I1 _k , I1 _k-1 , I1 _k-2 , I2 _k , I2 _k-1 and I2 _k-2 . 19. The method according to clause 16, wherein the power supply system includes a first phase (phase-a), a second phase (phase-b) and a third phase (phase-c), and digital logic circuits receive samples Ia, Ib and IC ; form the quantities Ia _k , Ia _k-1 , Ib _k , Ib _k-1 , Ic _k and Ic _k-1 and then make combinations of the values Ia _k , Ia _k-1 , Ib _k , Ib _k-1 , Ic _k and Ic _k-1 to obtain the values of I1 _k and I2 _k ; where Ia is the current in phase-a, Ib is the current in phase-b and Ic is the current in phase-c.  20. A device for generating non-stationary signals of positive symmetric sequences of components and negative symmetric sequences of components of voltages and currents of a power supply system, including: sampling means for obtaining samples of said currents of the power supply system; and digital logic circuits for generating positive symmetric sequences of components (I1) and negative symmetric sequences of components (I2) of the currents of the power supply system, including systems of delay elements, amplifying elements, and summing elements connected in the operational state to form digital symmetric components in real time, characterized in that the digital logic circuits form symmetrical components proportional to I1k and I2k, with I1 representing the current, put ln sequence, and I2 represents the current of the negative sequence, the subscript k refers to the digital samples of the corresponding components. 21. The device according to p. 20, characterized in that the power supply system includes a first phase (phase-a), a second phase (phase-b) and a third phase (phase-c), and digital logic circuits form Clark components:

where Ia represents the current in phase-a, 1b represents the current in phase-b and 1c represents the current in phase-c. 22. The device according to item 21, wherein the digital logic circuitry includes a first input terminal for receiving current Ia samples in phase-a, a second input terminal for receiving current Ib samples in phase-b, and a third input terminal for receiving current Ic samples in phase s; means for forming the quantities Iα _k , Iα _k-1 , Iβ _k and Iβ _k-1 ; and means for making combinations of the quantities Ια _k , Iα _k-1 , Iβ _k and Iβ _k-1 and obtain the values I1 _k , I1 _k-1 , I1 _k-2 , I2 _k , I2 _k-1 and I2 _k-2 . 23. The device according to p. 20, characterized in that the power supply system includes a first phase (phase-a), a second phase (phase-b) and a third phase (phase-c), and digital logic circuits include a first input terminal for receiving samples current Ia in phase-a, a second input terminal for receiving current Ib samples in phase-b and a third input terminal for receiving current Ic samples in phase-c; means for generating values of Ia _k , Ia _k-1 , Ib _k , Ib _k-1 , Ic _k and Ic _k-1 and means for generating combinations of the values Ia _k , Ia _k-1 , Ib _k , Ib _k-1 , Ic _k and Ic _k-1 to obtain the values of I1 _k and I2 _k , where Ia represents the current in phase-a, Ib represents the current in phase-b and Ic represents the current in phase-c.