DC CONVERTER VALVE STATE DETECTION METHOD BASED ON TEMPORAL FEATURES OF CONVERTER TERMINAL CURRENTS

Abstract

The present invention discloses a DC converter valve state detection method based on temporal features of converter terminal currents, including the following steps: collecting three-phase AC currents on a converter valve-side of a DC transmission system; defining a current when the currents of two commutating valves are equal as a base value, greater than the base value as a valve conducting current, and less than the base value as a valve blocking current; constructing a valve conducting state by a relative relationship among amplitudes of the three-phase AC currents, and calculating a time interval of each valve conducting state; comparing time intervals of 6 valve conducting states with a time interval of a valve conducting state in normal operation, and determining whether the 6 valve states are normal according to the result of comparison and locating all abnormal valves. The present invention can reliably detect valve states and locate abnormal valves through sequence detection. This method can be applied to actual fault phase judgment and commutation failure judgment, providing a good support for accurate judgment of DC control and protection.

Claims

1. A DC converter valve state detection method based on temporal features of converter terminal currents, comprising the following steps: S1. defining a HVDC transmission converter valve model, comprising a valve VT.sub.1, a valve VT.sub.2, a valve VT.sub.3, a valve VT.sub.4, a valve VT.sub.5, and a valve VT.sub.6, wherein the valve VT.sub.1 and the valve VT.sub.4 are connected in series to form a first branch, the valve VT.sub.3 and the valve VT.sub.6 are connected in series to form a second branch, the valve VT.sub.5 and the valve VT.sub.2 are connected in series to form a third branch, and the first, second, and third branches are connected in parallel, and wherein a connecting point between the valve VT.sub.1 and the valve VT.sub.4 in the first branch is defined as an a-phase measuring point of three-phase AC currents, a connecting point between the valve VT.sub.3 and the valve VT.sub.6 in the second branch is defined as a b-phase measuring point of the three-phase AC currents, a connecting point between the valve VT.sub.5 and the valve VT.sub.2 in the third branch is defined as a c-phase measuring point of the three-phase AC currents, and three-phase AC currents i.sub.a, i.sub.b and i.sub.c on a converter valve-side of a DC transmission system are collected, where i.sub.a, i.sub.b and i.sub.c represent an a-phase, a b-phase, and a c-phase of the three-phase AC currents respectively; S2. defining a current when the currents of two commutating valves are equal as a base value, greater than the base value as a valve conducting current, and less than the base value as a valve blocking current; S3. defining sequence detection as follows: a valve current relative relationship is constructed by a ratio of the valve conducting current to the valve current base value, a duty cycle of the valve current relative relationship being greater than a threshold is defined as a valve conducting state, and the valve conducting state is integrated within one cycle to construct a valve conduction time interval; and S4. according to the steps S2 and S3, comparing time intervals of valve conducting states of the valve VT.sub.1, the valve VT.sub.2, the valve VT.sub.3, the valve VT.sub.4, the valve VT.sub.5, and the valve VT.sub.6 with a time interval of a valve conducting state in normal operation, and determining whether the valve state is normal and locating an abnormal valve according to a result of comparison.

2. The DC converter valve state detection method based on temporal features of converter terminal currents according to claim 1, wherein the step S2 comprises: S21. obtaining valve currents i.sub.VT1, i.sub.VT2, i.sub.VT3, i.sub.VT4, i.sub.VT5 and i.sub.VT6 of the valve VT.sub.1, the valve VT.sub.2, the valve VT.sub.3, the valve VT.sub.4, the valve VT.sub.5, and the valve VT.sub.6 by calculating absolute values of the three-phase AC currents i.sub.a, i.sub.b and i.sub.c according to the following formula: $\begin{matrix} {\begin{matrix} i_{VT 1} = .Math. i_{a} .Math.; i_{a} < 0 \\ i_{VT 2} = .Math. i_{c} .Math.; i_{c} > 0 \\ i_{VT 3} = .Math. i_{b} .Math.; i_{b} < 0 \\ i_{VT 4} = .Math. i_{a} .Math.; i_{a} > 0 \\ i_{VT 5} = .Math. i_{c} .Math.; i_{c} < 0 \\ i_{VT 6} = .Math. i_{b} .Math.; i_{b} > 0 \end{matrix} & (1) \end{matrix}$ where i.sub.VT1 is the valve current of the valve VT.sub.1, i.sub.VT2 is the valve current of the valve VT.sub.2, i.sub.VT3 is the valve current of the valve VT.sub.3, i.sub.VT4 is the valve current of the valve VT.sub.4, i.sub.VT5 is the valve current of the valve VT.sub.5, and i.sub.VT6 is the valve current of the valve VT.sub.6; S22. calculating a maximum value of the absolute values of the three-phase AC currents i.sub.a, i.sub.b and i.sub.c as the valve current base value according to the following formula: $\begin{matrix} i_{b a s e} = \frac{\max (.Math. i_{a} .Math., .Math. i_{b} .Math., .Math. i_{c} .Math.)}{2} & (2) \end{matrix}$ where i.sub.base represents the valve current base value, |i.sub.a|, |i.sub.b| and |i.sub.c| represent the absolute values of the three-phase AC currents, and max(|i.sub.a|,|i.sub.b|,|i.sub.c|) represents the maximum value of the absolute values of the three-phase AC currents; and S23. defining the valve current being greater than the valve current base value as the valve conducting current according to the following formula:
i.sub.HVTm=i.sub.VTm;i.sub.VTm≥i.sub.base (3) where m=1 custom-character 23456, and i.sub.HVTm represents the valve conducting current.

3. The DC converter valve state detection method based on temporal features of converter terminal currents according to claim 1, wherein the step S3 comprises: S31. defining a ratio of the valve conducting current to the valve current base value as a valve current relative relationship S.sub.VT1, S.sub.VT2, S.sub.VT3, S.sub.VT4, S.sub.VT5 and S.sub.VT6 according to the following formula: $\begin{matrix} S_{V T m} = \frac{i_{HVTm}}{i_{b a s e}} & (4) \end{matrix}$ where S.sub.VTm represents the valve current relative relationship S.sub.VT1, S.sub.VT2, S.sub.VT3, S.sub.VT4, S.sub.VT5 and S.sub.VT6, m=1 custom-character 23456, i.sub.HVTm represents the valve conducting current, and i.sub.base represents the valve current base value; S32. calculating a valve current duty cycle of the valve current relative relationship S.sub.VTm through a single-phase comparator, and defining the valve current duty cycle being greater than K as the valve conducting state S.sub.HVTm according to the following formula:
S.sub.HVTm=S.sub.VTm; S.sub.VTm>K (5) where S.sub.HVTm is the valve conducting state, and K is a critical value considering calculation errors; and S33. according to the step S32, calculating a valve conduction time interval of the valve conducting state in each power frequency cycle with an integrator according to the following formula:
t.sub.HVTm=∫.sub.−T.sup.0S.sub.HVTmdt (6) where t.sub.HVTm is the valve conduction time interval, and T is the time interval of a power frequency cycle.

4. The DC converter valve state detection method based on temporal features of converter terminal currents according to claim 1, wherein the step S4 comprises: S41. during normal operation, triggering the valve VT.sub.1, the valve VT.sub.2, the valve VT.sub.3, the valve VT.sub.4, the valve VT.sub.5, and the valve VT.sub.6 of the three-phase to conduct in turn at 60° equal phase intervals, and according to the steps S2 and S3, calculating a time interval of each valve conducting state in normal operation according to the following formula: $\begin{matrix} t_{HVT_normal} = \frac{T}{3} & (7) \end{matrix}$ where t.sub.HVT_normal is the valve conduction time interval in normal operation, and T is the time interval of a power frequency cycle; S42. comparing the valve conduction time interval t.sub.HVTm calculated in the step S33 with the valve conduction time interval t.sub.HVT_normal in normal operation to determine whether each valve conducting state is abnormal according to the following formula: $\begin{matrix} {\begin{matrix} .Math. t_{{HVT}_{m}} - t_{HVT_normal} .Math. \leq ε; normal \\ .Math. t_{{HVT}_{m}} - t_{HVT_normal} .Math. > ε; abnormal \end{matrix} & (8) \end{matrix}$ where ε represents a sampling measurement error; and S43. locating an abnormal valve according to an output state from the valve conduction time interval through a range comparator according to the following formula: $\begin{matrix} {CS}_{HVTm} = {\begin{matrix} 2; t_{{HVT}_{m}} - t_{HVT_normal} > ε \\ 1; - ε \leq t_{{HVT}_{m}} - t_{HVT_normal} \leq ε \\ 0; t_{{HVT}_{m}} - t_{HVT_normal} < - ε \end{matrix} & (9) \end{matrix}$ where cs.sub.HVTm represents a valve state signal, 2 represents that the valve conducting state is lengthened, 1 represents that the valve conducting state is normal, and 0 represents that the valve conducting state is shortened.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] FIG. 1 is a schematic diagram of an HVDC transmission converter valve according to the present invention;

[0034] FIG. 2 is a waveform diagram of three-phase AC currents on the converter valve-side according to the present invention when the valve state is in normal operation, in which i.sub.a, i.sub.b and i.sub.c represents phases a, b, and c of the three-phase AC currents, i.sub.base represents that the current when the currents of two commutating valves are equal, and

[00007] $\frac{T}{3}$

represents the valve conduction time interval;

[0035] FIG. 3 is a logic diagram of sequence detection according to the present invention, in which i.sub.k represents collected currents of the three-phase AC currents on the converter valve-side, k=a custom-character b c, t.sub.HVTm represents the valve conduction time interval, cs.sub.HVTm, represents the signal of valve conducting state, and m=123456;

[0036] FIG. 4 is a flow chart of a DC converter valve state detection method based on temporal features of converter terminal currents according to the present invention, which is used to judge valve states and locating abnormal valves, where t.sub.HVTm represents the valve conduction time interval, m=1 custom-character 23456, and ε represents a sampling measurement error;

[0037] FIG. 5 is a schematic diagram of three-phase AC currents collected by a current transformer according to the present invention, in which i.sub.A1Y, i.sub.B1Y and i.sub.C1Y represents three-phase AC currents on the valve-side;

[0038] FIG. 6 is a schematic diagram of a valve current base value according to the present invention, in which i.sub.base represents the valve current base value;

[0039] FIG. 7 is a schematic diagram of a time interval signal by simulation output of sequence detection according to the present invention, in which t.sub.HVT1, t.sub.HVT2, t.sub.HVT3, t.sub.HVT4, t.sub.HVT5, and t.sub.HVT6 represent valve conduction time interval output signals, and an area between the dotted lines represents the valve conduction time interval t.sub.HVT_normal in normal operation; and

[0040] FIG. 8 is a schematic diagram of a valve state signal by simulation output of sequence detection according to the present invention, in which cs.sub.HVT1, cs.sub.HVT2, cs.sub.HVT3, cs.sub.HVT4, cs.sub.HVT5 and cs.sub.HVT6 represent valve state signals, 2 represents that the valve state is lengthened, 1 represents that the valve state is normal, and 0 represents that the valve state is shortened.

DETAILED DESCRIPTION

[0041] In order to make the objectives, technical solutions, and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be described clearly and completely in conjunction with the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are a part of the embodiments of the present invention, but not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative work shall fall within the protection scope of the present invention.

Embodiment I

[0042] This embodiment provides a DC converter valve state detection method based on temporal features of converter terminal currents. The method is implemented through the following technical solutions and includes the following steps:

[0043] S1. An HVDC transmission converter valve model is as shown in FIG. 1, and three-phase AC currents i.sub.a, i.sub.b and i.sub.c on a converter valve-side of a DC transmission system are collected.

[0044] S2. A current when the currents of two commutating valves are equal is defined as a base value i.sub.base, greater than the base value i.sub.base as a valve conducting current, and less than the base value i.sub.base as a valve blocking current, as shown in FIG. 2;

[0045] The step S2 specifically includes the following steps:

[0046] S21. According to the step S1, 6 valve currents i.sub.VT1, i.sub.VT2, i.sub.VT3, i.sub.VT4, i.sub.VT5 and i.sub.VT6 are obtained by calculating absolute values of the three-phase AC currents i.sub.a, i.sub.b and i.sub.c according to the following formula:

[00008] $\begin{matrix} {\begin{matrix} i_{V T 1} = .Math. i_{a} .Math.; i_{a} < 0 \\ i_{V T 2} = .Math. i_{c} .Math.; i_{c} > 0 \\ i_{V T 3} = .Math. i_{b} .Math.; i_{b} < 0 \\ i_{V T 4} = .Math. i_{a} .Math.; i_{a} > 0 \\ i_{V T 5} = .Math. i_{c} .Math.; i_{c} < 0 \\ i_{V T 6} = .Math. i_{b} .Math.; i_{b} > 0 \end{matrix} & (1) \end{matrix}$

[0047] where i.sub.VT1 is the valve current of the valve VT.sub.1, i.sub.VT2 is the valve current of the valve VT.sub.2, i.sub.VT3 is the valve current of the valve VT.sub.3, i.sub.VT4 is the valve current of the valve VT.sub.4, i.sub.VT5 is the valve current of the valve VT.sub.5, and i.sub.VT6 is the valve current of the valve VT.sub.6.

[0048] S22. The maximum value of the absolute values of the three-phase AC currents i.sub.a, i.sub.b and i.sub.c is calculated as the valve current base value according to the following formula:

[00009] $\begin{matrix} i_{b a s e} = \frac{\max (.Math. i_{a} .Math., .Math. i_{b} .Math., .Math. i_{c} .Math.)}{2} & (2) \end{matrix}$

[0050] S23. The valve current being greater than the valve current base value is defined as the valve conducting current according to the following formula:

i.sub.HVTm=i.sub.VTm;i.sub.VTm≥i.sub.base (3)

[0051] where m=1 custom-character 23456, and i.sub.HVTm represents the valve conducting current.

[0052] S3. Sequence detection is defined, and the logic is as shown in FIG. 3.

[0053] This step S3 specifically includes the following steps:

[0054] S31. A ratio of the valve conducting current to the valve current base value is defined as a valve current relative relationship and S.sub.VT1, S.sub.VT2, S.sub.VT3, S.sub.VT4, S.sub.VT5 and S.sub.VT6 according to the following formula:

[00010] $\begin{matrix} S_{V T m} = \frac{i_{HVTm}}{i_{b a s e}} & (4) \end{matrix}$

[0055] where m=1 custom-character 23456, and S.sub.VTm represents the valve current relative relationship S.sub.VT1, S.sub.VT2, S.sub.VT3, S.sub.VT4, S.sub.VT5 and S.sub.VT6.

[0056] S32. According to the step S31, a valve current duty cycle of the valve current relative relationship S.sub.VTm is calculated through a single-phase comparator, and the valve current duty cycle being greater than K is defined as the valve conducting state S.sub.HVTm according to the following formula:

S.sub.HVTm=S.sub.VTm; S.sub.VTm>K (5)

[0057] where m=1 custom-character 23456, S.sub.HVTm is the valve conducting state, and K is a critical value considering calculation errors.

[0058] S33. According to the step S32, a valve conduction time interval of the valve conducting state in each power frequency cycle is calculated with an integrator according to the following formula:

t.sub.HVTm=∫.sub.−T.sup.0S.sub.HVTmdt (6)

[0059] where m=1 custom-character 23456, t.sub.HVTm is the valve conduction time interval, and T is the time interval of a power frequency cycle.

[0060] S4. According to the steps S2 and S3, time intervals of valve conducting states of the valve VT.sub.1, the valve VT.sub.2, the valve VT.sub.3, the valve VT.sub.4, the valve VT.sub.5, and the valve VT.sub.6 are compared with a time interval of a valve conducting state in normal operation, and whether the valve state is normal is determined and an abnormal valve is located according to a result of comparison.

[0061] This step S4 specifically includes the following steps:

[0062] S41. During normal operation, six valves (VT.sub.1, VT.sub.2, VT.sub.3, VT.sub.4, VT.sub.5, and VT.sub.6) of the three-phase are triggered to conduct in turn at 60° equal phase intervals, and according to the steps S2 and S3, a time interval of each valve conducting state in normal operation is calculated according to the following formula:

[00011] $\begin{matrix} t_{HVT_normal} = \frac{T}{3} & (7) \end{matrix}$

[0063] where t.sub.HVT_normal is the valve conduction time interval in normal operation.

[0064] S42. The actual valve conduction time interval calculated in the step S33 is compared with the valve conduction time interval in normal operation to determine whether each valve conducting state is abnormal according to the following formula:

[00012] $\begin{matrix} {\begin{matrix} .Math. t_{{HVT}_{m}} - t_{HVT_normal} .Math. \leq ε; normal \\ .Math. t_{{HVT}_{m}} - t_{HVT_normal} .Math. \leq ε; abnormal \end{matrix} & (8) \end{matrix}$

[0065] where m=1 custom-character 23456, and ε represents a sampling measurement error.

[0066] S43. An abnormal valve is located according to an output state from the valve conduction time interval t.sub.HVTm through a range comparator according to the following formula. The valve state detection and positioning flowchart is as shown in FIG. 4;

[00013] $\begin{matrix} {CS}_{HVTm} = {\begin{matrix} 2; t_{{HVT}_{m}} - t_{HVT_normal} > ε \\ 1; - ε \leq t_{{HVT}_{m}} - t_{HVT_normal} \leq ε \\ 0; t_{{HVT}_{m}} - t_{HVT_normal} < - ε \end{matrix} & (9) \end{matrix}$

[0067] where m=1 custom-character 23456, ε represents a sampling measurement error, cs.sub.HVTm represents a valve state signal, 2 represents that the valve conducting state is lengthened, 1 represents that the valve conducting state is normal, and 0 represents that the valve conducting state is shortened.

Embodiment II

[0068] According to the DC converter valve state detection method based on temporal features of converter terminal currents in embodiment I, the calculation is carried out in an actual power grid project, and the present invention is further described in detail.

[0069] A current transformer collects three-phase AC currents i.sub.A1Y, i.sub.B1Y and i.sub.C1Y on a converter valve-side, and the waveforms are as shown in FIG. 5.

[0070] According to the amplitude information of the three-phase AC currents i.sub.A1Y, i.sub.B1Y and i.sub.C1Y in FIG. 5, 6 valve currents i.sub.VT1, i.sub.VT2, i.sub.VT3, i.sub.VT4, i.sub.VT5 and i.sub.VT6 are obtained, and a valve current base value is defined, as shown in FIG. 6. The valve current being greater than the valve current base value is defined as a valve conducting current.

[0071] Sequence detection is defined, and the logic is as follows: a valve current relative relationship is constructed through a ratio of the valve conducting current to the valve current base value, a duty cycle of the valve current relative relationship being greater than a threshold is defined as a valve conducting state, and the valve conducting state is integrated within one cycle to construct a valve conduction time interval, as shown in FIG. 7.

[0072] According to the comparison between the valve conduction time interval and the valve conduction time interval in normal operation, a valve state signal cs.sub.HVTm is obtained to detect whether the valve state is abnormal, and an abnormal valve is located. cs.sub.HVTm=2 represents that the valve conducting state is lengthened, cs.sub.HVTm=1 represents that the valve conducting state is normal, and cs.sub.HVTm=0 represents that the valve conducting state is shortened, as shown in FIG. 8.

[0073] In summary, the above embodiments provide a DC converter valve state detection method based on temporal features of converter terminal currents, which is targeted to accurately detect valve conducting states and locate abnormal valves, providing a good support for accurate judgment of DC control protection.

[0074] The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above embodiments, and any other changes, modifications, substitutions, combinations, simplifications, etc. made without departing from the spirit and principle of the present invention all should be equivalent replacement methods, and they are all included in the protection scope of the present invention.

DC CONVERTER VALVE STATE DETECTION METHOD BASED ON TEMPORAL FEATURES OF CONVERTER TERMINAL CURRENTS

Inventors

Cpc classification

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H02M1/0009

ELECTRICITY

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G01R31/263

PHYSICS

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H02M7/7575

ELECTRICITY

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Y02E60/60

GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS

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H02M1/32

ELECTRICITY

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G01R31/42

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G01R31/56

PHYSICS

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G01R31/3275

PHYSICS

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H02J3/36

ELECTRICITY

International classification

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G01R31/56

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Abstract

Claims

Description