CN111224384A - Method for comparing line voltage vector difference on two sides of line and protecting line breakage by adopting loop closing and opening operation - Google Patents

Abstract

The invention discloses a protection method for line breaking by ring closing and opening operation for comparing line voltage vector differences on two sides of a line. The invention adopts a relay protection scheme that the voltage information at two sides of the line is transmitted through the optical fiber channel of the line, the line voltage vector difference at two sides of the line is compared to identify the line disconnection, and the load end transformer station transfers the load power supply by adopting the loop closing and opening operation, so that the transformer losing the power supply recovers to the standby power supply to supply power, thereby effectively preventing the influence of the transformer on the power grid and the load power supply due to the phase failure power supply and being beneficial to the safe and stable operation of the power grid.

Description

Method for comparing line voltage vector difference on two sides of line and protecting line breakage by adopting loop closing and opening operation

Technical Field

The invention relates to a protection method for comparing vector differences of line voltages on two sides of a line and adopting loop closing and opening operation to break the line, belonging to the technical field of protection and control of power transmission and distribution networks.

Background

At present, the line disconnection phenomenon of 3-66 kV (including 3, 6, 10, 20, 35 and 66kV) lines occurs in power grids in various places, and the line disconnection causes the phase-loss operation of a transformer supplied by the lines, so that the three-phase voltage of the transformer is asymmetric, the influence is generated on load power supply, electrical equipment can be damaged, for example, a motor is damaged due to the phase-loss operation. In the prior art, no relay protection device and method specially aiming at the disconnection of a 3-66 kV line exist. The invention provides a single-phase line-breaking relay protection method which is characterized in that a load-end substation transmits voltage information on two sides of a line through a line optical fiber channel, compares line voltage vector differences on the two sides of the line to identify line breaking, and transfers load power supply by adopting ring closing and opening operation.

Disclosure of Invention

The invention aims to provide a single-phase disconnection relay protection method which is used for comparing line voltage vector differences on two sides of a line, adopts a closing and opening loop operation disconnection protection method, is used for a load end 3-66 kV transformer substation, transmits voltage information on two sides of the line through a line optical fiber channel, compares the line voltage vector differences on two sides of the line, identifies line disconnection, and adopts a closing and opening loop operation to transfer load power supply by the load end transformer substation.

The purpose of the invention is realized by the following technical scheme:

a protection method for comparing vector difference of line voltages on two sides of a line and adopting loop closing and opening operation disconnection comprises the following steps:

judging the condition of tripping off the incoming line breaker of the line-breaking line after the line-breaking line closes the standby breaker of the load end transformer substation

1.1 judging the conditions of No. 1 line broken line closing load end substation standby circuit breaker 2DL or 3DL and tripping No. 1 incoming line circuit breaker 1DL, and starting No. 1 line broken line alarm condition

Collecting secondary AB line voltage of power supply side bus PT

BC line voltage

CA line voltage

No. 1 line power supply side circuit breaker 4DL switching-on position information, load end I section bus PT secondary AB line voltage of transformer substation

BC line voltage

CA line voltage

1DL switching-on position information of a breaker on a load side of a No. 135kV power incoming line; sending the power supply side signal to the disconnection protection in the load substation line protection of the No. 1 line;

conditions are as follows: (1) no. 1 line power supply side bus PT secondary AB line voltage vector

And load end I section bus PT secondary AB line voltage vector of transformer substation

Absolute value of vector difference, power supply side bus PT secondary BC line voltage vector

And load end I section bus PT secondary BC line voltage vector of transformer substation

Absolute value of vector difference, power supply side bus PT secondary CA line voltage vector

And load end transformer substation I section bus PT secondary CA line voltage vector

The absolute value of the vector difference of (1), two of the absolute values of the three vector differences being 0.519E_abTo 0.953E_abOne is less than or equal to 0.1E_ab；E_abThe rated line voltage value of the power supply;

(2) power supply end corresponding bus PT secondary AB line voltage value U_A1B1Greater than or equal to 0.9E_ab1.1E or less_ab；

(3) Power supply end corresponding bus PT secondary BC line voltage value U_B1C1Greater than or equal to 0.9E_ab1.1E or less_ab；

(4) Power supply end corresponding bus PT secondary CA line voltage value U_C1A1Greater than or equal to 0.9E_ab1.1E or less_ab；

(5) The power end 35kV line breaker 4DL of the No. 1 line is at the switching-on position;

(6) the load end 35kV line breaker 1DL of the No. 1 line is at the switching-on position;

if the conditions are all met, identifying and judging that the No. 1 power line is disconnected, protecting the load end transformer substation No. 1 line from disconnection, starting to close the standby power circuit breaker 2DL or 3DL, and then tripping the No. 1 power line load side circuit breaker 1DL to recover the transformer without power supply to the standby power line for power supply; simultaneously starting No. 1 line disconnection alarm;

1.2 judging the condition of No. 2 line broken line closing load end substation standby circuit breaker 1DL or 3DL and tripping No. 2 incoming line circuit breaker 2DL, and starting the condition of No. 2 line broken line alarm

Collecting secondary AB line voltage of power supply side bus PT

BC line voltage

CA line voltage

No. 2 line power supply side circuit breaker 5DL switching-on position information, load end substation II section bus PT secondary AB line voltage

BC line voltage

CA line voltage

2DL switching-on position information of a breaker at the load side of a No. 2 power incoming line; sending the power supply side signal to the disconnection protection in the load substation line protection of the No. 1 line;

(1) no. 2 line power supply side bus PT secondary AB line voltage vector

Secondary AB line voltage vector of II-section bus PT of transformer substation at load end

Absolute value of vector difference, power supply side bus PT secondary BC line voltage vector

And the load terminal transformerSecondary BC line voltage vector of II-section bus PT (potential Transformer) of power station

Absolute value of vector difference, power supply side bus PT secondary CA line voltage vector

And load end substation II section bus PT secondary CA line voltage vector

The absolute value of the vector difference of (1), two of the absolute values of the three vector differences being 0.519E_abTo 0.953E_abOne is less than or equal to 0.1E_ab；E_abThe rated line voltage value of the power supply;

(2) power supply end corresponding bus PT secondary AB line voltage value U_A1B1Greater than or equal to 0.9E_ab1.1E or less_ab；

(3) Power supply end corresponding bus PT secondary BC line voltage value U_B1C1Greater than or equal to 0.9E_ab1.1E or less_ab；

(4) Power supply end corresponding bus PT secondary CA line voltage value U_C1A1Greater than or equal to 0.9E_ab1.1E or less_ab；

(5) A power end 35kV line breaker 5DL of the No. 2 line is at a switching-on position;

(6) the load end 35kV line breaker 2DL of the No. 2 line is at the switching-on position;

and if the conditions are all met, identifying and judging that the No. 2 power supply circuit is broken, carrying out broken line protection in the No. 2 circuit protection of the load-side substation, and after starting closing the standby power supply circuit breaker 1DL or 3DL, tripping off the No. 2 power supply circuit load-side circuit breaker 2DL to enable the transformer losing the power supply to recover to the standby power supply circuit for power supply. And simultaneously, starting No. 2 line disconnection alarm.

The object of the invention can be further achieved by the following technical measures:

the vector difference of the line voltages at the two sides of the comparison line adopts a loop closing and opening operation disconnection protection method, and is applied to a mode that a neutral point of a transformer is not grounded or is grounded through an arc suppression coil and a small-resistance grounding system.

Comparing the vector difference of line voltages on two sides of the line, adopting a ring closing and opening operation disconnection protection method, and obtaining a rated line voltage value E of a PT secondary side_abIs 100V.

And (3) comparing the vector difference of the line voltages at the two sides of the line, adopting a ring closing and opening operation line breaking protection method, wherein t1 is 0.1-0.2 second when three phases are not in phase when the breaker is closed.

Compared with the prior art, the invention has the beneficial effects that:

1. the invention fully utilizes the fault characteristics of the secondary voltage of the power supply end and load end substation bus PT when the single-phase line is broken, compares the voltage vector difference of the buses at the two ends of the line, identifies the single-phase line break of the line, and transfers the load power supply by the load end substation by adopting the ring closing and opening operation, thus being simple and easy.

2. The invention adopts a relay protection scheme that the voltage information at two sides of the line is transmitted through the optical fiber channel of the line, the line voltage vector difference at two sides of the line is compared to identify the line disconnection, and the load end transformer station transfers the load power supply by adopting the loop closing and opening operation, so that the transformer losing the power supply recovers to the standby power supply to supply power, thereby effectively preventing the influence of the transformer on the power grid and the load power supply due to the phase failure power supply and being beneficial to the safe and stable operation of the power grid.

3. The method of the invention is implemented by adopting the line protection devices at two sides of the line, and does not need to increase hardware equipment.

Drawings

FIG. 1 is a schematic diagram of a primary system of a superior substation with 35kV side not grounded or grounded through an arc suppression coil;

FIG. 2 is a vector diagram of the voltage of a 35kV bus on the power supply side without grounding or through arc suppression coils;

FIG. 3 is a vector diagram of the voltage of a 35kV bus on the load side without grounding or through an arc suppression coil;

FIG. 4 is a schematic diagram of a primary system with a 35kV line break and a load side line break grounded;

FIG. 5 is a vector diagram of the voltage of a 35kV bus on the load side at a load side disconnection point;

FIG. 6 is a schematic diagram of a primary system with a 35kV line broken and a power supply side grounded;

FIG. 7 is a vector diagram of the voltage of a 35kV bus at the ground power supply side at a power supply side disconnection;

FIG. 8 is a vector diagram of the voltage of a 35kV bus at the grounded load side at the power supply side disconnection;

fig. 9 is a schematic diagram of a primary system of a superior substation with 35kV side grounded through a resistor;

FIG. 10 is a vector diagram of 35kV bus voltage at the 35kV side of the upper-level substation via the resistance grounding power supply side;

fig. 11 is a voltage vector diagram of a 35kV bus at a 35kV side of an upper-level substation through a resistance grounding load side;

FIG. 12 is a schematic diagram of a primary system with a 35kV line break and a load side line break grounded;

FIG. 13 is a vector diagram of the voltage of a 35kV bus at the load side which is grounded at a load side disconnection;

FIG. 14 is a schematic diagram of a 35kV primary system with a power supply side disconnected and a ground connection;

FIG. 15 is a schematic diagram of the disconnection protection of the present invention;

FIG. 16 is a primary main wiring diagram of a single bus segment of a 35kV substation;

FIG. 17 is a primary main wiring diagram of an inner bridge of a 35kV substation;

FIG. 18 is a primary main wiring diagram of an enlarged inner bridge of a 35kV substation;

fig. 19 is a primary main connection of a 35kV line transformer set of a 35kV substation.

Detailed Description

The invention is further described with reference to the following figures and specific examples.

Firstly, analyzing fault characteristics by taking 35kV line breakage as an example:

1.1 ungrounded or arc-suppression coil grounding system

1.1.135kV line broken wire

Fig. 1 is a schematic diagram of a 35kV primary disconnection system, taking an a-phase stub as an example. The 35kV side of the upper-level transformer substation is not grounded or is grounded through an arc suppression coil, and the 35kV neutral point of the 35kV transformer substation on the load side is not grounded. The power supply potentials at 35kV sides of the upper-level transformer substation are respectively set as E_A、E_B、E_C，U_NFor the voltage of the 35kV neutral point of the transformer of the power side substation, if α line breaks, the capacitance to ground of the bus side of the upper level substation from the line break is α C, the capacitance to ground of the 35kV bus of the transformer substation from the line break to the load side is (1- α) C.1, and the voltage analysis of the bus of the power side

Analyzing to obtain the voltage of a bus at the 35kV side of the upper-level transformer substation as follows:

(1) in the formula (I), the compound is shown in the specification,

the voltage of a power side 35kV bus A1B1 line, the voltage of a B1C1 line and the voltage of a C1A1 line are respectively. ,

the method is characterized in that the voltage of power supply lines at 35kV side of a superior substation is equal in size, a voltage vector diagram of 35kV bus at the power supply side is shown in figure 2, as can be seen from figure 2, when the line A of a 35kV line is disconnected, the voltage of three-phase line of the 35kV bus at the superior substation is constant and keeps symmetrical, α in the diagram is changed between 0 and 1, and 0 point is shown as 0 in figure 2_α＝0To 0_α＝1When α is equal to 1, point 0 is at 0_α＝1At point, when α is 0, 0 is at 0_α＝0(the same applies below).

2. Load side bus voltage analysis

The 35kV load side bus voltage is analyzed as follows:

(2) in the formula (I), the compound is shown in the specification,

the line voltage of the load side 35kV bus A2B2, the line voltage of B2C2 and the line voltage of C2A2 are shown in a vector diagram of the load side 35kV bus in figure 3.

As can be seen from FIG. 3, when the 35kV line is disconnected, the load side

Is composed of

Is equal to

1.1.235 kV line disconnection and load side disconnection grounding

Fig. 4 is a schematic diagram of a 35kV line break and load side line break grounding primary system, taking an a-phase stub as an example. The 35kV side of the upper-level transformer substation is not grounded, and the 35kV neutral point of the 35kV transformer substation on the load side is not grounded. The power supply potentials at 35kV sides of the upper-level transformer substation are respectively set as E_A、E_B、E_C，U_NThe capacitance to ground of the 35kV bus of the transformer substation from the broken line to the upper-level substation is α C, and the capacitance to ground of the 35kV bus of the transformer substation from the broken line to the load side is (1- α) C.

1. Power supply side bus voltage analysis

The analysis was as in 1.1.1.

2. Load side bus voltage analysis

The 35kV load side bus voltage is analyzed as follows:

the vector diagram of the 35kV bus voltage on the load side is shown in figure 5.

As can be seen from FIG. 5, when the 35kV line is broken and the load side broken line is grounded,

is equal to

α varies between 0 and 1 according to the distance of the broken line close to the power supply side bus bar, and simultaneously

In that

To a change of 0, point 0 being as in FIG. 5 0_α＝0To 0_α＝1The number of the intermediate change is changed,

in that

To

While varying between

In that

To

And (4) change.

1.1.335kV line disconnection and power supply side disconnection point grounding

Fig. 6 is a schematic diagram of a primary system with a 35kV line broken and a power supply side grounded, taking an a-phase short line as an example. The 35kV side of the upper-level transformer substation is not grounded, and the 35kV neutral point of the 35kV transformer substation on the load side is not grounded. The power supply potentials at 35kV sides of the upper-level transformer substation are respectively set as E_A、E_B、E_C，U_NThe capacitance to ground of the 35kV bus of the transformer substation from the broken line to the upper-level substation is α C, and the capacitance to ground of the 35kV bus of the transformer substation from the broken line to the load side is (1- α) C.

1. Power supply side bus voltage analysis

Analyzing the voltage of a bus at the 35kV side of the upper-level transformer substation:

the vector diagram of the 35kV bus voltage at the power supply side is shown in figure 7.

As can be seen from fig. 7, when the 35kV line is disconnected and the power supply side is grounded, the three line voltages are constant and symmetrical.

2. Load side bus voltage analysis

The 35kV load side bus voltage is analyzed as follows:

the vector diagram of the 35kV bus voltage on the load side is shown in figure 8.

When the 35kV line is broken, the load side

Is composed of

Is equal to

1.2 grounding System via a resistor

1.2.135 kV line broken wire

Fig. 9 is a schematic diagram of a 35kV primary disconnection system, taking an a-phase stub as an example. The 35KV power supply system of the 35kV side transformer substation of the upper-level transformer substation is grounded through a resistor (R is generally 10, 20 and 100 omega). The power supply potentials at 35kV sides of the upper-level transformer substation are respectively set as E_A、E_B、E_C，U_NAnd if α line breaks are set for the 35kV neutral point voltage of the transformer substation on the power supply side, the capacitance to ground of the bus side of the transformer substation from the line break position to the upper level is α C, and the capacitance to ground of the bus of the transformer substation from the line break position to the load side is (1- α) C.

1. Power supply side bus voltage analysis

Analyzing to obtain the voltage of a bus at the 35kV side of the upper-level transformer substation as follows:

(6) in the formula (I), the compound is shown in the specification,

respectively, 35k on the power supply sideV bus A1B1 line voltage, B1C1 line voltage, C1A1 line voltage. The vector diagram of the 35kV bus voltage on the power supply side is shown in FIG. 10.

As can be seen from fig. 10, when a phase a of the 35kV line is disconnected, the voltages of the three-phase lines of the 35kV bus of the upper-level substation are unchanged and are kept symmetrical. With the distance of the broken line close to the power supply side bus bar different, the 0 point is 0 in FIG. 10_α＝0To 0_α＝1When α is equal to 1, point 0 is at 0_α＝1At point, when α is 0, 0 is at 0_α＝0(same below) with U_NAt about ω CE_AThe variation from R to 0 (the cable line capacitance C is generally less than or equal to 0.55 mu F, and the overhead line is even smaller, so U_NIs a very small value, and is 0.55 mu F, U according to the grounding resistance of 20 omega, C_NIs 3.45^-3E_AAnd so can be ignored).

2. Load side bus voltage analysis

The 35kV load side bus voltage is analyzed as follows:

(7) in the formula (I), the compound is shown in the specification,

the line voltage of the load side 35kV bus A2B2, the line voltage of B2C2 and the line voltage of C2A2 are shown in a vector diagram of the load side 35kV bus in the figure 11.

As can be seen from FIG. 11, when the 35kV line is disconnected, the load side

Is composed of

And

in the opposite direction and of magnitude

1.2.235 kV line disconnection and load side disconnection grounding

Fig. 12 is a schematic diagram of a 35kV line break and load side line break grounding primary system, taking an a-phase stub as an example. The 35KV power supply system of the 35kV side transformer substation of the upper-level transformer substation is grounded through a resistor. The power supply potentials at 35kV sides of the upper-level transformer substation are respectively set as E_A、E_B、E_C，U_NThe capacitance to ground of the 35kV bus of the transformer substation from the broken line to the upper-level substation is α C, and the capacitance to ground of the 35kV bus of the transformer substation from the broken line to the load side is (1- α) C.

1. Power supply side bus voltage analysis

The analysis was as in 1.2.1.

2. Load side bus voltage analysis

The 35kV load side bus voltage is analyzed as follows:

the vector diagram of the 35kV bus voltage on the load side is shown in FIG. 13.

As can be seen from FIG. 13, when the 35kV line is disconnected and the load side disconnection is grounded, U is turned off_B2C2Is equal to E_BCAnd the distance is different along with the distance of the broken line close to the power supply side bus. Due to U_NCan be ignored, so U_A2B2、U_C2A2Is about equal to E_BAnd E_C。

1.2.335 kV line disconnection and power supply side disconnection point grounding

Fig. 14 is a schematic diagram of a primary system with a 35kV line broken and a power supply side grounded, taking an a-phase short line as an example. The 35KV power supply system of the 35kV side transformer substation of the upper-level transformer substation is grounded through a resistor. The power supply potentials at 35kV sides of the upper-level transformer substation are respectively set as E_A、E_B、E_C，U_NThe capacitance to ground of the 35kV bus of the transformer substation from the broken line to the upper-level substation is α C, and the capacitance to ground of the 35kV bus of the transformer substation from the broken line to the load side is (1- α) C.

When the line is broken and the system side is grounded, the fault is a single-phase grounding short circuit fault, so that the zero sequence current protection action of the system transformer substation line trips, and reclosure cannot be coincided.

Analyzing the line breaking fault characteristics of the 3-66 kV line:

for three conditions of ungrounded, arc suppression coil grounded and resistance grounded systems, 35kV line breakage and load side line breakage grounded, 35kV line breakage and power supply side line breakage grounded, the power supply side line voltage is constant and symmetrical (for the resistance grounded systems, when the line breakage and system side grounded, single-phase grounding short circuit fault occurs, the zero-sequence current protection of the line trips actions).

Due to the grounding condition of the broken line of the 35kV line and the broken line of the power supply side, U_NCan be ignored, so for the two conditions of 35kV line disconnection, 35kV line disconnection and grounding at the power supply side disconnection, the load side bus line voltage and the load side

Is equal to

Is equal to

For the case that the 35kV line is broken and the load side is grounded,

is equal to

α varies between 0 and 1 according to the distance of the broken line close to the power side bus,

in that

To

While varying between

In that

To

And (4) change.

In summary, when three conditions of 35kV line disconnection, 35kV line disconnection with grounding at the load side disconnection point, 35kV line disconnection with grounding at the power side disconnection point occur, the absolute value of the line voltage vector difference between the two sides of the line satisfies:

similarly, when a 3-66 kV line is broken, the bus line voltages on two sides of the line have the same fault characteristics.

The technical scheme of the method of the invention is as follows:

the transmission and distribution network applied by the method is 35kV single-bus subsection primary main connection (including 35kV single-bus primary main connection), 35kV inner bridging connection (shown in figure 17), 35kV expansion inner bridging connection (shown in figure 18) and 35kV line transformation group primary main connection (shown in figure 19) of a 35kV substation. Taking a 35kV substation as an example of a primary main connection of a 35kV single-bus subsection, other primary main connection protection methods are similar (in which fig. 19 is matched with a medium-voltage or low-voltage spare power automatic switch to recover power supply). The 35kV single-bus subsection primary main wiring general structure of the 35kV substation is as follows: the No. 1 power supply incoming line branch equipment and the No. 2 power supply incoming line branch equipment are respectively connected with a 35kV I section bus and a 35kV II section bus; a segmented circuit breaker 3DL is arranged between the 35kV first-segment bus and the second-segment bus, and the segmented circuit breaker 3DL is connected with a segmented current transformer CT in series; the circuit breaker 1DL is arranged at the interval of the No. 1 power supply inlet branch circuit, the circuit breaker 2DL is arranged at the interval of the No. 2 power supply inlet branch circuit, and the No. 1 power supply inlet branch circuit and the No. 2 power supply inlet branch circuit are respectively connected with a current transformer CT1 and a current transformer CT2 in series; in addition, the 35kV I section bus is also connected with a No. 1 transformer branch and a 35kV voltage transformer PT 1; the 35kV II section bus is also connected with a No. 2 transformer branch and a 35kV voltage transformer PT 2. There is circuit breaker 4DL No. 1 power inlet wire circuit power supply side, and there is circuit breaker 5DL No. 2 power inlet wire circuit power supply side. No. 1 power supply inlet wire power end 35kV bus is connected with 35kVPT3, and No. 2 power supply inlet wire power end 35kV bus is connected with 35kVPT 4. The 35kV line is provided with an optical fiber channel and line optical fiber differential protection.

Aiming at the 35kV single-bus subsection primary main connection, the single-phase disconnection relay protection scheme that the load end 35kV transformer substation transfers load power supply by adopting a ring closing operation is adopted to meet the field operation requirement by implementing the transmission of voltage information on two sides of a line through a 35kV line optical fiber channel in an upper-stage transformer substation, comparing line voltage vector differences on two sides of the line to identify the disconnection of the 35kV line.

As shown in fig. 15, the method for comparing the vector difference of line voltages on two sides of a line and protecting the line breaking by loop closing and opening operations of the invention comprises the following steps:

judging condition of tripping off line break circuit incoming breaker of 35kV transformer substation after closing load end standby breaker of 35kV line break

1.1 judging the conditions of 2DL or 3DL of a standby circuit breaker of a 35kV transformer substation at the on-load end of a No. 135kV circuit broken line and 1DL of a No. 1 trip incoming line circuit breaker, and starting a No. 135kV circuit broken line alarm condition

Acquisition power source side 35kV bus PT secondary AB line voltage

BC line voltage

CA line voltage

No. 135kV line power supply side circuit breaker 4DL switching-on position information, load end 35kV transformer substation I section bus PT secondary AB line voltage

BC line voltage

CA line voltage

1DL switching-on position information of a breaker on a load side of a No. 135kV power incoming line; sending the power supply side signal to 35kV disconnection protection in 35kV line protection of a No. 135kV line load 35kV transformer substation;

conditions are as follows: (1) no. 135kV line power supply side bus PT secondary AB line voltage vector

And load end I section bus PT secondary AB line voltage vector of transformer substation

Absolute value of vector difference, power supply side bus PT secondary BC line voltage vector

And load end I section bus PT secondary BC line voltage vector of transformer substation

Absolute value of vector difference, power supply side bus PT secondary CA line voltage vector

And load end transformer substation I section bus PT secondary CA line voltage vector

The absolute value of the vector difference of (1), two of the absolute values of the three vector differences being 0.519E_abTo 0.953E_abOne is less than or equal to 0.1E_ab；E_abThe rated line voltage value of the power supply;

(2) power end corresponds 35kV generating line PT secondary AB line voltage value U_A1B1Greater than or equal to 0.9E_ab1.1E or less_ab；

(3) Power supplyEnd-corresponding 35kV bus PT secondary BC line voltage value U_B1C1Greater than or equal to 0.9E_ab1.1E or less_ab；

(4) Power end corresponds 35kV generating line PT secondary CA line voltage value U_C1A1Greater than or equal to 0.9E_ab1.1E or less_ab；

(5) A power end 35kV line circuit breaker 4DL of the No. 135kV line is at the switching-on position;

(6) a load end 35kV line breaker 1DL of a No. 135kV line is at a switching-on position;

if the conditions are all met, identifying and judging that the No. 135kV power line is broken, carrying out 35kV broken line protection in No. 135kV line protection of a 35kV transformer substation at a load end, and tripping off a No. 135kV power line load side circuit breaker 1DL after switching on a standby power circuit breaker 2DL or 3DL to enable a transformer without a power supply to recover to the standby power line for power supply; simultaneously starting No. 135kV line disconnection alarm;

1.2 judging the conditions of 1DL or 3DL of the spare circuit breaker of the 35kV transformer substation at the on-load end of the No. 2 35kV circuit disconnection and 2DL of the trip No. 2 incoming line circuit breaker, and starting the condition of the No. 2 35kV circuit disconnection alarm

Acquisition power source side 35kV bus PT secondary AB line voltage

BC line voltage

CA line voltage

No. 2 35kV line power supply side circuit breaker 5DL switching-on position information, load end 35kV transformer substation II section bus PT secondary AB line voltage

BC line voltage

CA line voltage

2DL switching-on position information of a breaker at the load side of a No. 2 35kV power supply incoming line; sending the power supply side signal to 35kV disconnection protection in 35kV line protection of a No. 135kV line load 35kV transformer substation;

(1) no. 2 35kV line power supply side bus PT secondary AB line voltage vector

Secondary AB line voltage vector of II-section bus PT of transformer substation at load end

Absolute value of vector difference, power supply side bus PT secondary BC line voltage vector

Secondary BC line voltage vector of II-section bus PT (potential transformer) of transformer substation at load end

Absolute value of vector difference, power supply side bus PT secondary CA line voltage vector

And load end substation II section bus PT secondary CA line voltage vector

The absolute value of the vector difference of (1), two of the absolute values of the three vector differences being 0.519E_abTo 0.953E_abOne is less than or equal to 0.1E_ab；E_abThe rated line voltage value of the power supply;

(2) power end corresponds 35kV generating line PT secondary AB line voltage value U_A1B1Greater than or equal to 0.9E_ab1.1E or less_ab；

(3) Power end corresponds 35kV generating line PT secondary BC line voltage value U_B1C1Greater than or equal to 0.9E_ab1.1E or less_ab；

(4) Power end corresponds 35kV generating line PT secondary CA line voltage valueU_C1A1Greater than or equal to 0.9E_ab1.1E or less_ab；

(5) A power end 35kV line circuit breaker 5DL of a No. 2 35kV line is at a switching-on position;

(6) a load end 35kV line breaker 2DL of a No. 2 35kV line is at a switching-on position;

and if the conditions are all met, identifying and judging that the No. 2 35kV power line is broken, protecting the 35kV broken line in the No. 2 kV 35kV line protection of the load-end 35kV transformer substation, and tripping off the No. 2 No. 35kV power line load-side circuit breaker 2DL after starting to close the standby power circuit breaker 1DL or 3DL so as to recover the transformer without the power supply to the standby power line for power supply. And simultaneously, starting No. 2 35kV line disconnection alarm.

1.3 in 1.1 and 1.2 above:

(1) the method can be applied to a transformer neutral point ungrounded mode or arc suppression coil grounded mode and a small-resistance grounded system.

(2) The reason that the circuit breakers 1DL or 2DL, 4DL or 5DL on the two sides of the 35kV power inlet wire are arranged at the switching-on position is as follows: when a 35kV transformer substation with a load end of a power supply incoming line is used, the bus voltage far away from the power supply incoming line can also sense the line disconnection information, and the action behavior of the device can be interfered; in addition, when a line PT is adopted, the power supply incoming line may have other load end 35kV substations, and if the power supply incoming line breaker of the load end 35kV substation trips slowly or refuses tripping, the action behavior of the device can be interfered. The condition that the circuit breakers on the two sides of the inlet wire of the 35kV power supply are in the switching-on position can further optimize logic.

(3)E_abFor the rated line voltage value of the power supply, the voltage fluctuation of the power grid is considered, and the voltage fluctuation is considered according to +/-10% of the rated voltage value of the actual power grid, wherein: when the voltage value is larger than or equal to the rated line voltage value, the rated line voltage value of the power grid is considered to be 0.9 times; the rated line voltage value is less than or equal to 1.1 times of the rated voltage value of the power grid.

(4) For the bus load of the load side transformer substation which is in open-phase operation due to wire breakage, the method of firstly closing the standby power supply circuit breaker and then tripping the load side circuit breaker of the broken line is adopted in the load side transformer substation, the load is automatically transferred, and the power supply is restored to the standby line. If the 35kV transformer substation adopts primary main wiring of 35kV line transformer group, the method that the standby power supply circuit breaker is closed firstly and then the load side transformer high-voltage side circuit breaker and the load side transformer low-voltage side circuit breaker of the broken line are tripped is adopted by the low-voltage side of the load side transformer substation, so that the load is automatically transferred and is restored to the standby bus for power supply.

(5) And voltage information and circuit breaker position information on two sides of the line are transmitted through the line optical fiber channel.

2. The operation mode of a 35kV neutral point of a main transformer on a first section or a second section of a bus of a load end 35kV transformer substation is ungrounded; no. 1 and No. 2 power supply 35kV lines are required to be provided with optical fiber channels and line optical fiber differential protection.

3. The method can be implemented in a single 35kV line disconnection protection device of a load-end 35kV transformer substation or can also be implemented in a 35kV line protection device; the 35kV line protection device implemented in the 35kV transformer substation at the load end has the advantages that: no additional hardware devices are required.

4. The setting value of the PT secondary two-side voltage when the buses on the two sides of the circuit are broken is as follows:

dividing the secondary line voltages of a power supply side bus PT and a load end bus PT into three groups according to AB line voltage, BC line voltage and CA line voltage for comparison, wherein the setting value of the difference between the line voltages of the power supply side and the load end is as follows:

(1) two of the two groups of the setting values of the difference between the line voltage of the power supply side and the line voltage vector of the load side meet the following requirements: greater than or equal to the rated line voltage value of 51.9 percent

And is less than or equal to 95.3 percent of rated line voltage value

The PT secondary rated line voltage value is 100V, namely more than or equal to 51.9V and less than or equal to 95.3V;

(2) and the setting value of the difference between the line voltage of the power supply side and the line voltage vector of the load end is less than or equal to 10 percent of the rated line voltage value, namely less than or equal to 10V.

The setting value of the PT secondary line voltage of the power supply side bus meets the following requirements: the voltage value of the rated line is more than or equal to 90 percent and less than or equal to 110 percent, namely more than or equal to 90V and less than or equal to 110V.

5. After the 35kV line is judged to be disconnected, the load end 35kV transformer substation adopts a setting value of time in the single-phase disconnection relay protection method for switching the load power supply by ring closing and opening operation:

t 1: avoiding the three-phase different-period time when the switch is switched on, and taking 0.1-0.2 second;

6. the scheme of the invention can meet the following primary main wiring: (1) a 35kV single-bus subsection primary main wiring of a 35kV transformer substation; (2) a 35kV transformer substation 35kV inner bridge primary main wiring; (3) a 35kV transformer substation 35kV enlarges primary main wiring; (4) a 35kV transformer substation 35kV line group-changing primary main wiring; (5) other primary main connections.

7. For a 35kV line with branch lines, 35kV line breakage protection of pairwise correspondence between a power end-load end substation and each load end substation needs to be implemented.

8. The scheme of the invention can also be used in the case of the disconnection of a 110kV line powered by a single power supply.

An example of the process of the invention is given below (taking fig. 16 as an example):

operation mode 1:

under this operational mode, 2DL of No. 2 power circuit breaker, the operation of segmentation circuit breaker 3DL, 1DL of No. 1 power circuit breaker is hot standby, 1DL of No. 1 power circuit breaker branch floodgate position promptly.

For example, if phase A is broken, phase B or phase C is broken similarly. When the phase-A single-phase disconnection fault of the No. 2 35kV power supply circuit occurs, abnormal operation of the circuit is sensed through the value of the line voltage vector difference of 35kV buses on two sides, meanwhile, the line voltage of a power end substation 35kV bus PT is normal, the condition that the phase-A single-phase disconnection of the No. 2 kV power supply circuit occurs is met, after the time delay t1, the line disconnection protection of the 35kV circuit in the line protection of a load end is carried out, after the circuit breaker 1DL of the No. 1 kV standby power supply circuit breaker is started to be switched on, the circuit breaker 2DL of the No. 2 kV power supply incoming line of the load end 35kV substation is switched off, and the transformer losing the power supply is enabled. And reporting the single-phase disconnection fault of the No. 2 35kV power line.

Operation mode 2:

under this operational mode, 1DL of power breaker, 3DL operation of section circuit breaker, 2 # power breaker 2DL are hot standby, 2 # power breaker 2DL separating brake position promptly.

For example, if phase A is broken, phase B or phase C is broken similarly. When the phase-A single-phase disconnection fault of the No. 135kV power supply circuit occurs, abnormal operation of the circuit is sensed through the value of the vector difference of the voltages of the 35kV buses on the two sides, meanwhile, the voltages of the 35kV buses PT secondary lines of the power end substation are normal, the condition that the phase-A single-phase disconnection of the No. 135kV power supply circuit is met, after the time delay t1, the 35kV circuit in the load end circuit protection is disconnected, after the 2 # 35kV standby power supply circuit breaker 2DL is started to be switched on, the 1 # 35kV power supply incoming circuit breaker 1DL of the load end 35kV power substation is switched off, and the transformer losing the power supply is enabled to be recovered to the power supply of the. And simultaneously reporting the single-phase line break fault of the No. 135kV power line.

Operation mode 3:

under this operational mode, 1DL of No. 1 power circuit breaker, 2DL of No. 2 power circuit breaker operate, and the hot reserve of section circuit breaker 3DL, section circuit breaker 3DL separating brake position promptly.

No. 135kV power line single-phase disconnection fault:

for example, if phase A is broken, phase B or phase C is broken similarly. When the phase-A single-phase disconnection fault of the No. 135kV power supply circuit occurs, abnormal operation of the circuit is sensed through the value of the vector difference of the voltages of the 35kV buses on the two sides, meanwhile, the voltages of the 35kV buses PT secondary lines of the power end substation are normal, the condition that the phase-A single-phase disconnection of the No. 135kV power supply circuit is met, after the time delay t1, the 35kV circuit in the load end circuit protection is disconnected, after the 35kV standby power supply circuit breaker 3DL is started to be switched on, the No. 1DL of the load end substation 35kV power supply incoming circuit breaker is switched off, and the transformer losing the power supply is recovered to the No. 2 35kV standby power supply. And simultaneously reporting the single-phase line break fault of the No. 135kV power line.

No. 2 35kV power line single-phase disconnection fault:

for example, if phase A is broken, phase B or phase C is broken similarly. When the phase-A single-phase disconnection fault of the No. 2 35kV power supply circuit occurs, abnormal operation of the circuit is sensed through the value of the vector difference of the voltages of the 35kV buses on the two sides, meanwhile, the voltages of the 35kV buses PT secondary of a power end substation are normal, the condition that the phase-A single-phase disconnection of the No. 2 35kV power supply circuit is met, after the time delay t1, the 35kV circuit in the load end circuit protection is disconnected, after the 35kV standby power supply circuit breaker 3DL is started to be switched on, the No. 2 35kV power supply circuit load side circuit breaker 5DL is jumped, and the transformer losing power supply is recovered to the standby No. 135kV power supply circuit. And reporting the single-phase disconnection fault of the No. 2 35kV power line.

In addition to the above embodiments, the present invention may have other embodiments, and any technical solutions formed by equivalent substitutions or equivalent transformations fall within the scope of the claims of the present invention.

Claims (4)

1. A protection method for comparing vector difference of line voltages on two sides of a line and adopting loop closing and opening operation disconnection is characterized by comprising the following steps:

judging the condition of tripping off the incoming line breaker of the line-breaking line after the line-breaking line closes the standby breaker of the load end transformer substation

1.1 judging the conditions of No. 1 line broken line closing load end substation standby circuit breaker 2DL or 3DL and tripping No. 1 incoming line circuit breaker 1DL, and starting No. 1 line broken line alarm condition

Collecting secondary AB line voltage of power supply side bus PT

BC line voltage

CA line voltage

No. 1 line power supply side circuit breaker 4DL switching-on position information, load end I section bus PT secondary AB line voltage of transformer substation

BC line voltage

CA line voltage

1DL switching-on position information of a breaker on a load side of a No. 135kV power incoming line; sending the power supply side signal to the disconnection protection in the load substation line protection of the No. 1 line;

conditions are as follows: (1) no. 1 line power supply side bus PT secondary AB line voltage vector

And load end I section bus PT secondary AB line voltage vector of transformer substation

Absolute value of vector difference, power supply side bus PT secondary BC line voltage vector

And load end I section bus PT secondary BC line voltage vector of transformer substation

Absolute value of vector difference, power supply side bus PT secondary CA line voltage vector

And load end transformer substation I section bus PT secondary CA line voltage vector

The absolute value of the vector difference of (1), two of the absolute values of the three vector differences being 0.519E_abTo 0.953E_abOne is less than or equal to 0.1E_ab；E_abThe rated line voltage value of the power supply;

(2) power supply end corresponding bus PT secondary AB line voltage value U_A1B1Greater than or equal to 0.9E_ab1.1E or less_ab；

(3) Power supply end corresponding bus PT secondary BC line voltage value U_B1C1Greater than or equal to 0.9E_ab1.1E or less_ab；

(4) Power supply end corresponding bus PT secondary CA line voltage value U_C1A1Greater than or equal to 0.9E_ab1.1E or less_ab；

(5) The power end 35kV line breaker 4DL of the No. 1 line is at the switching-on position;

(6) the load end 35kV line breaker 1DL of the No. 1 line is at the switching-on position;

if the conditions are all met, identifying and judging that the No. 1 power line is disconnected, protecting the load end transformer substation No. 1 line from disconnection, starting to close the standby power circuit breaker 2DL or 3DL, and then tripping the No. 1 power line load side circuit breaker 1DL to recover the transformer without power supply to the standby power line for power supply; simultaneously starting No. 1 line disconnection alarm;

1.2 judging the condition of No. 2 line broken line closing load end substation standby circuit breaker 1DL or 3DL and tripping No. 2 incoming line circuit breaker 2DL, and starting the condition of No. 2 line broken line alarm

Collecting secondary AB line voltage of power supply side bus PT

BC line voltage

CA line voltage

No. 2 line power supply side circuit breaker 5DL switching-on position information, load end substation II section bus PT secondary AB line voltage

BC line voltage

CA line voltage

2DL switching-on position information of a breaker at the load side of a No. 2 power incoming line; sending the power supply side signal to the disconnection protection in the load substation line protection of the No. 1 line;

(1) no. 2 line power supply side bus PT secondary AB line voltage vector

Secondary AB line voltage vector of II-section bus PT of transformer substation at load end

Absolute value of vector difference, power supply side bus PT secondary BC line voltage vector

Secondary BC line voltage vector of II-section bus PT (potential transformer) of transformer substation at load end

Absolute value of vector difference, power supply side bus PT secondary CA line voltage vector

And load end substation II section bus PT secondary CA line voltage vector

The absolute value of the vector difference of (1), two of the absolute values of the three vector differences being 0.519E_abTo 0.953E_abOne is less than or equal to 0.1E_ab；E_abThe rated line voltage value of the power supply;

(2) power supply end corresponding bus PT secondary AB line voltage value U_A1B1Greater than or equal to 0.9E_ab1.1E or less_ab；

(3) Power supply end corresponding bus PT secondary BC line voltage value U_B1C1Greater than or equal to 0.9E_ab1.1E or less_ab；

(4) Power supply end corresponding bus PT secondary CA line voltage value U_C1A1Greater than or equal to 0.9E_ab1.1E or less_ab；

(5) A power end 35kV line breaker 5DL of the No. 2 line is at a switching-on position;

(6) the load end 35kV line breaker 2DL of the No. 2 line is at the switching-on position;

and if the conditions are all met, identifying and judging that the No. 2 power supply circuit is broken, carrying out broken line protection in the No. 2 circuit protection of the load-side substation, and after starting closing the standby power supply circuit breaker 1DL or 3DL, tripping off the No. 2 power supply circuit load-side circuit breaker 2DL to enable the transformer losing the power supply to recover to the standby power supply circuit for power supply. And simultaneously, starting No. 2 line disconnection alarm.

2. The method for protecting line disconnection by comparing the vector difference of line voltages on two sides of a line according to claim 1 is applied to a mode that a neutral point of a transformer is not grounded or is grounded through an arc suppression coil and a low-resistance grounding system.

3. The method for protecting line disconnection by comparing the vector difference of line voltages on two sides of a line according to claim 1 by adopting a loop closing and opening operation, wherein a rated line voltage value E on the secondary side of PT (potential transformer)_abIs 100V.

4. The method for protecting line breaking by comparing the vector difference of line voltages on two sides of a line according to claim 1 and adopting loop closing operation is characterized in that t1 is 0.1-0.2 second when three phases are not in phase when a breaker is closed.

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