CN113765059A

CN113765059A - Differential protection method suitable for main transformer of photovoltaic power station

Info

Publication number: CN113765059A
Application number: CN202111003366.0A
Authority: CN
Inventors: 安源; 李乐; 郝治国; 孟瑾; 苏瑞; 杨仁志; 郑申印; 耿辉; 石赫晨宇
Original assignee: Xian University of Technology
Current assignee: Xian University of Technology
Priority date: 2021-08-30
Filing date: 2021-08-30
Publication date: 2021-12-07

Abstract

The invention discloses a differential protection method suitable for a main transformer of a photovoltaic power station, which comprises the following steps: collecting three-phase currents on two sides of a main transformer differential protection of a photovoltaic power station when the main transformer differential protection is locked through a current transformer, and obtaining three-phase differential currents through phasor summation; comparing the difference value between the second harmonic phase and the double phase of the fundamental wave, and determining the change time of the difference value as the mutation time of the differential current; and calculating a second harmonic ratio of the three-phase differential current at the moment of sudden change of the differential current, comparing whether the second harmonic ratio is higher than a fault fixed value, if so, protecting the opening and cutting off the fault until the second harmonic ratio is lower than the fixed value of the inrush current, and protecting the closing and the locking. The differential protection of the main transformer of the photovoltaic power station can still reliably distinguish the internal fault state and open in time when the differential protection is locked and suffers from internal faults due to two types of inrush currents, and the action refusing of protection caused by high-content second harmonic waves due to short-circuit current provided by a photovoltaic power supply is prevented.

Description

Differential protection method suitable for main transformer of photovoltaic power station

Technical Field

The invention belongs to the technical field of transformers, and relates to a differential protection method suitable for a main transformer of a photovoltaic power station.

Background

The differential protection is one of main protections configured for the main transformer of the photovoltaic power station, has the advantages of reliably distinguishing internal and external faults of a protection area, instantaneously removing the internal faults and avoiding the interferences such as excitation surge current and the like, and plays an extremely important role in the safe operation of the photovoltaic power station. In most cases, in order to meet the requirements of power grid dispatching and auxiliary power and natural energy fluctuation characteristics, main transformers in a photovoltaic power station are mostly switched between a working state and a shutdown state, terminal voltage of one main transformer is suddenly changed due to no-load switching-on of the main transformer, iron core magnetic flux saturation is caused, and excitation inrush current is generated. In addition, when the main transformer has an in-zone fault, the short-circuit current provided by the photovoltaic power supply may contain a large second harmonic content due to the existence of power electronic devices such as inverters in the photovoltaic power generation units. Therefore, when the main transformer differential protection of the photovoltaic power station is locked due to two types of inrush currents and suffers from internal faults, due to high-content second harmonics caused by short-circuit current provided by the photovoltaic power supply, the protection is mistaken to continue to be locked in an inrush current state during the internal faults, and therefore the protection cannot be opened in time to remove the internal faults and generate rejection.

Disclosure of Invention

The invention aims to provide a differential protection method suitable for a main transformer of a photovoltaic power station, and solves the problem that in the prior art, when differential protection locked by inrush current has an internal fault, the protection cannot be opened in time to remove the internal fault due to high-content second harmonic waves caused by short-circuit current provided by a photovoltaic power supply, so that action rejection is generated.

The invention adopts the technical scheme that the differential protection method suitable for the main transformer of the photovoltaic power station comprises the following steps:

step 1, collecting two-side three-phase currents when the main transformer differential protection of the photovoltaic power station is locked through a current transformer

Obtaining three-phase differential current through phasor summation;

step 2, comparing the difference value delta theta of the second harmonic phase and the double phase of the fundamental wave in the three-phase differential current, and determining the change time of the delta theta value as the mutation time of the differential current;

step 3, calculating the second harmonic ratio K of the three-phase differential current at the moment of sudden change of the differential current_dComparison K_dWhether or not it is higher than a constant value K_dset,faultIf K is_dHigher than a constant value K_dset,faultThen the fault is removed until K_dConstant value K below inrush current_dset,inrushAnd the protection exits the locking.

The invention is also characterized in that:

the differential current abrupt change timing is a timing at which the value of Δ θ fluctuates around 0 ° or 180 °.

Constant value K_dset,faultTake the maximum value during the duration of the inrush current.

K of inrush current_dset,inrushTaking the fixed value of 0.15-0.2 of the conventional inrush current blocking.

The change time of the delta theta value is obtained by adopting a curve fitting method in a numerical integration discipline.

The invention has the beneficial effects that:

the differential protection method applicable to the main transformer of the photovoltaic power station can ensure that the differential protection of the main transformer of the photovoltaic power station can still reliably and correctly distinguish the internal fault state and open in time when the inrush current blocking state exists; based on the fact that the second harmonic ratio of differential current is higher than the maximum value of the second harmonic ratio when the differential protection of a main transformer of a photovoltaic power station has internal faults, the second harmonic ratio fixed value at the moment of the internal faults is established, so that the differential protection is opened in time to remove the faults, the differential protection rejection caused by high-content second harmonic waves when the photovoltaic system has the internal faults is prevented, and the differential protection working mode with excellent distinguishing performance is established.

Drawings

FIG. 1 is a flow chart of a differential protection method for a main transformer of a photovoltaic power station according to the present invention;

FIG. 2 is a schematic diagram of differential protection simulation of the differential protection method for the main transformer of the photovoltaic power station according to the present invention;

FIG. 3 is a waveform diagram of three-phase differential current and second harmonic ratio in the presence of inrush current and faults in a differential protection method for a main transformer of a photovoltaic power station according to the present invention;

fig. 4 is a diagram of a change law of a differential current phase difference in a differential protection method applicable to a main transformer of a photovoltaic power station.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

A differential protection method suitable for a main transformer of a photovoltaic power station, as shown in fig. 1, includes the following steps:

Obtaining three-phase differential current through phasor summation;

step 2, comparing the difference value delta theta of the second harmonic phase and the double phase of the fundamental wave in the three-phase differential current, and determining the time when the delta theta fluctuates at 0 degrees or 180 degrees as the sudden change time of the differential current;

the principle of judging the sudden change time of the differential current is as follows: the change of a delta theta value in the differential current in the inrush current locking process is obtained by adopting a curve fitting method in a numerical integration discipline according to the existing fault current recording data: since the decay rate of the free component of the sympathetic inrush current is slow, the value of delta theta is basically kept at 0 degrees or 180 degrees, while the decay rate of the free component of the short-circuit current at the time of the fault is fast, and the value of delta theta fluctuates around 0 degrees or 180 degrees. Therefore, the occurrence timing of the fault current in the differential current can be discriminated from the value of Δ θ.

Step 3, calculating the second harmonic ratio K of the sudden change moment according to the three-phase differential current_dComparison K_dWhether or not it is higher than a constant value K_dset,faultIf K is_dHigher than a constant value K_dset,faultThen the fault is removed until K_dConstant value K below inrush current_dset,inrushProtection quit locking; wherein, the constant value K_dset,faultTaking the maximum value in the continuous process of the inrush current and the constant value K of the inrush current_dset,inrushTaking the fixed value of 0.15-0.2 of the conventional inrush current blocking.

Through the mode, the differential protection method applicable to the main transformer of the photovoltaic power station can ensure that when the differential protection of the main transformer of the photovoltaic power station is in the inrush blocking state, the internal fault state can still be reliably and correctly distinguished and opened in time under the condition of high-content second harmonic waves brought by a photovoltaic system when the internal fault occurs; based on the fact that the second harmonic ratio of differential current is higher than the maximum value of the second harmonic ratio when the differential protection of a main transformer of a photovoltaic power station has internal faults, the second harmonic ratio fixed value at the moment of the internal faults is established, so that the differential protection is opened in time to remove the faults, the differential protection rejection caused by the problem of high content of second harmonic waves brought by the internal faults of a photovoltaic system is prevented, and the differential protection working mode with excellent distinguishing performance is established.

Examples

As shown in fig. 2, in the present embodiment, a photovoltaic power station simulation model with a capacity of 50MW is provided, a transformer T1 is set to be switched on in an unloaded state, and a fault occurs at f1 in a protection area of an operating transformer T2.

Three-phase differential currents are obtained through phasor summation, and are shown in FIG. 3;

step 2, comparing the difference value delta theta of the second harmonic phase and the double phase of the fundamental wave in the three-phase differential current, obtaining the change characteristic of the delta theta through cosine curve fitting, and determining the time when the delta theta fluctuates at 0 degrees or 180 degrees as the mutation time of the differential current, wherein the change characteristic is shown in fig. 4;

step 3, calculating the second harmonic ratio K of the three-phase differential current at the sudden change moment_dComparison K_dWhether or not it is higher than a constant value K_dset,faultIf K is_dHigher than a constant value K_dset,faultThen the fault is removed until K_dK below inrush current_dset,inrushProtection quit locking; wherein, three-phase K after various internal faults are simulated_d,faultHigher than the maximum value K during the duration of the inrush current_d,inrushTo set, see Table 1, for a constant value of K_dset,inrushTaking conventional 0.15-0.2.

TABLE 1 second harmonic ratio at different internal faults

Claims

1. A differential protection method suitable for a main transformer of a photovoltaic power station is characterized by comprising the following steps:

step 1, collecting three-phase currents on two sides of main transformer differential protection of photovoltaic power station when locking through current transformer

Obtaining three-phase differential current through phasor summation;

step 3, calculating a second harmonic ratio K of the three-phase differential current at the moment of sudden change of the differential current_dComparison K_dWhether or not it is higher than a constant value K_dset,faultIf K is_dHigher than a constant value K_dset,faultThen the fault is removed until K_dConstant value K below inrush current_dset,inrushAnd the protection exits the locking.

2. The differential protection method for the main transformer of the photovoltaic power station as claimed in claim 1, wherein the time of the differential current abrupt change is a time when the value of Δ θ fluctuates around 0 ° or 180 °.

3. The differential protection method for main transformer of photovoltaic power station as claimed in claim 1, characterized in that said constant value K is_dset,faultTake the maximum value during the duration of the inrush current.

4. The differential protection method applicable to the main transformer of the photovoltaic power station as claimed in claim 1, wherein the K of the inrush current is_dset,inrushTaking the fixed value of 0.15-0.2 of the conventional inrush current blocking.

5. The differential protection method for the main transformer of the photovoltaic power station as claimed in claim 1, wherein the variation time of the Δ θ value is obtained by a curve fitting method in numerical integration discipline.