RU150530U1 - TRANSFORMER DIFFERENTIAL PROTECTION UNIT - Google Patents

Abstract

A transformer differential protection unit, comprising, a phase-by-phase differential current driver proportional to the sum of the secondary currents on the sides of the transformer to be protected, a brake current driver, which is a function of the secondary currents and phases between them, a differential current control unit, a setpoint unit for comparing the differential current with the setpoint and brake current, the output relay of the protection device, characterized in that a magnetization inrush measurement unit is introduced, an additional unit braking, quick shutdown unit, OR circuit and logic unit, while the outputs of the magnetizing current inrush measurement unit and the auxiliary braking unit are connected to one of the OR circuits, the output of which is connected to input Y, a logic unit, whose input X is connected to the output of the settings block and input Z - with the output of the differential current block, the outputs of the logic block and the quick disconnect block are connected to the corresponding inputs of another OR circuit, the output of which is connected to the output relay of the protection device.

Description

The claimed technical solution relates to the relay protection of electrical systems against short circuits (short circuit) and can be used to protect transformers.

From the existing level of technology it is known that the main purpose of relay protection is to identify the occurrence of short circuit and the quick automatic shutdown of a damaged network element. The most widespread are protection with secondary relays of indirect action, requiring additional sources of operating current. To power the operational circuits, sources of direct and alternating current are used. Sources of direct operating current are universal, but require separate circuits, equipment, maintenance, and therefore are used in large distribution substations. At small substations there is only variable operational power. With short circuit in external circuits, this voltage strongly “drops”, which requires the use of special accumulative power sources or protection relays that do not require a separate source of operational power. Measuring current circuits can also be used to power the protection relay, provided that the power consumption does not exceed the specified values. Current transformers are a reliable source of power for operational circuits for protection against short-circuit, since during short-circuit current increases at the terminals of the current transformer, therefore, at the moment of protection operation, the power of the current transformer increases, which ensures reliable supply of operational circuits.

, и

, полученных от трансформаторов тока, установленных на противоположных сторонах защищаемого объекта. В дифференциальных защитах с торможением для улучшения селективности действия защиты при внешних КЗ дифференциальный ток, равный сумме токов

, сравнивают с уставкой срабатывания и отдельно формируемым тормозным током I_T, при превышении которых дифференциальным током вырабатывают сигнал на отключение защищаемой электроустановки.Differential protection is based on phase-by-phase comparison of secondary currents

, and

obtained from current transformers installed on opposite sides of the protected object. In differential protections with braking, to improve the selectivity of the protection during external short-circuit, a differential current equal to the sum of the currents

, are compared with the setpoint of operation and separately generated braking current I _T , above which the differential current generates a signal to turn off the protected electrical installation.

Known differential current relay with braking DZT-11 and others [1], designed for differential protection of one phase of power transformers, in which the differential protection is braked by unbalance current due to saturation of the intermediate transformer. Relays provide braking from one group of measuring current transformers and do not require a separate operating current source for operation. The disadvantages of this technical solution [1] are: 1) low sensitivity; 2) the braking current does not depend on the phase ratios of the controlled currents; 3) high energy consumption from measured current circuits.

There is a method of differential protection, according to which to improve the detuning from external short-circuit and current surges of unbalance, the time-pulse principle is used, based on the analysis of the duration of pauses in the differential current curve [1]. The disadvantages of this technical solution [1] is low noise immunity, which reduces the reliability of the protection. In addition, with internal short-circuit currents close to the tripping setpoint and the presence of an aperiodic component in the short-circuit currents, the response time of the protection increases significantly.

A device [2] is known for differential cutoff of a transformer connected to a differential circuit of secondary windings of measuring current transformers and containing a relay of maximum alternating current, a high-quality parallel resonant oscillatory circuit of 50 Hz. The disadvantages of this technical solution [2] - there is no braking function and a relatively large protection response time.

A device [3] is known for quickly locking the transformer diffuser during inrush currents of magnetization, containing electronic circuits of multiplication, integration, rectification, comparison and decision making. The disadvantages of this technical solution [3] are the technical complexity and the requirement for a source of operating current.

It is known that modern protections are performed on the basis of programmable microprocessor terminals [4]. In them, either the maximum current of one of the sides or the sum of the modules of the currents of the sides is taken as the braking current. The disadvantages of this technical solution [4] are: 1) the need for a separate source of operating current; 2) the braking current does not depend on the phase ratios of the controlled currents; 3) complexity and high cost.

A known method of differential protection of electrical installations, implemented in a programmable microprocessor-based terminal of differential protection [5]. The terminal phase-wise implements, in particular, the functions of generating a differential current, generating a braking current proportional to the square root of the scalar product of the phase current vectors measured on different sides of the protected electrical installation, and the function of the reacting organ in which the differential current is compared with the setpoint and braking current. The disadvantages of the technical solution [5]: 1) during the operation of such protections, external short-circuit modes are observed in which false alarms are possible due to transients; 2) the need for a separate source of operating current; 3) complexity and high cost.

Closest to the claimed technical solution is the method of differential protection of an electrical installation selected as a prototype [6], in which to eliminate the need to reduce the sensitivity of protection in order to avoid its operation in case of external short-circuit, accompanied by intense transient processes, they form a differential current that is proportional to the difference of the secondary currents by the input and output of the protected electrical installation, and the braking current, consisting of two terms, the first of which is proportional to the root of the quad atomic from the vector product of the indicated secondary currents, and the values of the second are calculated by integrating an additional current equal to the difference between the sum of the modules of the indicated secondary currents and the differential current module, drag down the decay of the second term of the braking current, compare the differential current with the setpoint and the braking current, and issue signal for protection operation (shutdown of the electrical installation).

The disadvantages of the prototype - when working protections that implement the method [6], requires complex algorithms for the formation of braking current, characteristic of complex and expensive terminal protection devices. It also requires the presence of continuous operational power sources. For the relay protection of power transformers of distribution networks where variable operational power is used, this method is not suitable.

The tasks to which the claimed technical solution is directed is to ensure the selectivity of the protection during external faults, accompanied by intense transients, without reducing its sensitivity with the possibility of using this device in transformer protections where there are no sources of operating current, as well as improving reliability and simplifying the device.

The technical result provided by the given set of features is the elimination of the need to reduce the sensitivity of the protection in order to avoid its operation in case of external short-circuit, accompanied by intensive transients, the possibility of using this device in transformer protections, where there are no sources of operating current, for example, when upgrading transformer protection from short-circuit, built differential current relay with braking DZT-11 TU 16-523.464-74 and others.

Disclosure of a technical solution

This problem is solved due to the fact that the claimed technical solution, the differential protection unit of the transformer, characterized in that it does not require a separate operating current source, compares the differential current with the setpoint and braking current and, according to the results of the comparison, gives a signal for the protection to be activated, turns on the differential phase-by-phase driver current proportional to the sum of the secondary currents on the sides of the protected transformer, the brake current shaper, which is a function of the values of the secondary currents and phases between them so that at constant values of currents, the dependence of the braking current on the phase between the currents is presented as a function of the cardioid, as well as additional blocks for monitoring the second harmonic level of the differential signal, monitoring the differential current, differential cutoff and inhibit braking.

Brief Description of the Drawings

The essence of the claimed technical solution is illustrated by drawings. Figures 1 and 2 show the comparative functional dependences of the braking current on the phase between the vectors of the compared controlled currents, in orthogonal and polar coordinates, respectively: 1, 4 - for DZT-11 relays and other various relays, in which the braking current is determined as the sum of the modules side currents or as the maximum current of one of the sides of the protected transformer; 2, 5 - for the prototype in the absence of short circuit; 3, 6 - for the claimed technical solution. According to the claimed technical solution, a transformer relay protection block has been developed. Figure 3 presents a block diagram of the measuring part of the device with a power module. Figure 4 presents a functional diagram of the operation of the device.

The device operates as follows.

Since differential protection operates in phase, a further description is given for each phase of protection.

,

,

, измеренных по разные стороны защищаемого объекта, формируются вспомогательные токи

, и

, равные:The brake current is generated according to the following algorithm. From the amplitudes and phases of the secondary phase currents

,

,

measured on different sides of the protected object, auxiliary currents are formed

, and

equal to:

Differential current is defined as the geometric sum of the source currents:

The braking current value I _T is determined by the function of the cardioid:

и

. Такая характеристика тормозного тока позволяет плавно увеличивать чувствительность срабатывания при внутренних КЗ, когда оба вектора тока

, и

направлены в одну сторону.where θ is the angle between

and

. This characteristic of the braking current allows you to smoothly increase the response sensitivity for internal short circuit, when both current vectors

, and

directed one way.

The graph of the functional dependence of (4) I _T on θ is shown in Fig. 1 (in Cartesian coordinates) and Fig. 2 (in polar coordinates), curves 3 and 6. For comparison, graphs of similar dependencies for DZT-11 and various other relays in which the braking current is defined as the sum of the modules of the currents of the sides or as the maximum current of one of the sides of the protected transformer (curves 1 and 4), and for the prototype in the absence of a short circuit (curves 2 and 5).

The block diagram of the measuring part of the device with a power module is presented in figure 3 and contains the following functional blocks:

7 ... 9 - secondary measuring current transformers (TT1-TT3);

10 - power module (MP);

11 ... 13 - alignment schemes (CB1-CB3);

14 ... 17 - shapers of analog signals (FS1-FS4);

18 - digital signal processing (DSP).

The electronic part of the protection unit is designed using a low current microcontroller. Given the optimization of the program code and the choice of a simpler algorithm for generating the braking current than the prototype, the device consumes no more than the permissible power from the measuring current circuits. The power module 10 generates the necessary energy to power the circuit and stores the energy that is used to hold the output relay of the device until the transformer is turned off.

The input measuring currents I ₁ ... I ₃ sides of the protected transformer are supplied to the secondary current transformers 7-9. The outputs of these transformers are connected to the power module 10 and the alignment circuit 11-13 to align the base currents of the sides of the protected transformer. From the outputs of blocks 11-13, the measured signals are fed to signal conditioners 14-17, where preliminary frequency filtering and amplitude selection are performed. In block 17 is also the formation of a differential signal. The received signals from the outputs of blocks 14-17 are sent to the digital signal processing unit 18, which is made programmatically. After processing, in block 18, secondary signals are obtained for use in the differential protection triggering logic: i ₁ , i ₂ , i ₃ , - digitized values of the currents of the first harmonic I ₁ -I ₃ ; I _{1_2} - second harmonic of the differential current; I ′ ₁ and I ′ ₂ - values of auxiliary currents; I _D is the differential current; I _T is the braking current. Secondary signals from the outputs of block 18 are further processed in the microcontroller of the device according to the functional diagram shown in figure 4.

The functional diagram in figure 4 consists of:

19 - block settings;

20 - unit for measuring the inrush of the magnetization current;

21 - block additional braking;

22 - differential current control unit;

23 - block quick shutdown;

24 ... 26 - blocks of logical operations;

27 - output relay device.

The setpoint block 19, comparing the differential current values with the setpoint and the braking current, generates a logical protection trip / release signal. Block 20 generates a logic signal to block the protection operation depending on the level of the second harmonic in the differential current spectrum, which recognizes the inrush currents of the magnetization of the transformer. Block 21 generates a logic signal to block the operation of the protection depending on the values of auxiliary currents I ′ ₁ and I ′ ₂ for additional blocking with external faults. Block 22 generates a logic signal to block the operation of the protection by monitoring the behavior of the differential current when the protection is turned on. Block 23 generates a logic signal for tripping when the differential current exceeds the cutoff tripping setpoint. Blocks 24, 25, 26 are the logical processing of the output signals of blocks 19-23. From the outputs of blocks 20 and 21, the signals are sent to block 24 (logical OR circuit). Block 25 is a logical operation diagram X∧¬Y∧¬Z, where X, Y, Z are the inputs of the block. The input X of block 25 is connected to the output of block 19, the input Y of block 25 is connected to the output of block 20, the input Z of block 25 is connected to the output of block 22. The output of block 25 and the output of block 23 are connected to the inputs of block 26, which is a logical OR circuit. The output of block 26 is connected to block 27 - the output relay of the protection device.

Based on the claimed technical solution in the form of a utility model of a differential transformer protection block, a transformer protection block BRZT-11 was developed for production. It is supposed to be used to modernize existing protection against short-circuit transformer substations, where there are no additional sources of direct operating current. Currently, they use differential protection relays with braking DZT-11.

Information sources

1. N.V. Chernobrovov, V.A. Semenov. Relay protection of energy systems. M .: Energoatomizdat, 1998, S.595-606.

2. RU 2356153 C1 05.20.2009. Relays for differential transformer cutoff.

3. RU 2368990 C1 09/27/2009. Electronic device for quick blocking of transformer differential protection.

4. E.M. Schneerson. Digital relay protection. M .: Energoatomizdat, 2007. S.239-244.

5. ABB MODULES. Digital generator protection. Type REG 216. Work instructions. ABB Edition Relay-Cheboksary. January 1994.

6. RU 2261510 C1 02.26.2004. The method of differential protection of electrical installations.

Claims (1)

A transformer differential protection unit, comprising, a phase-by-phase differential current driver proportional to the sum of the secondary currents on the sides of the transformer to be protected, a brake current driver, which is a function of the secondary currents and phases between them, a differential current control unit, a setpoint unit for comparing the differential current with the setpoint and brake current, the output relay of the protection device, characterized in that a magnetization inrush measurement unit is introduced, an additional unit braking, quick shutdown unit, OR circuit and logic unit, while the outputs of the magnetizing current inrush measurement unit and the auxiliary braking unit are connected to one of the OR circuits, the output of which is connected to input Y, a logic unit, whose input X is connected to the output of the settings block and input Z - with the output of the differential current block, the outputs of the logic block and the quick disconnect block are connected to the corresponding inputs of another OR circuit, the output of which is connected to the output relay of the protection device.

Images