LV15156B - Device and method for relay protection of electrical network - Google Patents

Abstract

The invention relates to high and medium voltage networks and substations. The network is formed by a transmission line with power system elements connected to its terminal buses as well as by a simplified connection that is located in the transmission line, with one high-voltage circuit-breaker. On the first and the second buses, protection terminals are installed, but at the place of the simplified connection, in addition to the relay protection, a verification device is installed, which monitors the operability of the communication channel(-s) and the local protection device. This verification device operates in cases when different failures occur in the communication system and in the local protection device. Also in the case when a failure occurs in the verification device, the local protection device emits a pulse and the circuit breaker is switched off. To diminish the total investment in the new connection, maintaining the required accuracy and selectivity of relay protection, the offered new solution of relay protection device is provided with an additional verification device, which continuously monitors the condition of the communication system and the local protection.

Description

Description of the Invention

The invention relates to high-voltage and distribution electrical networks and substations. The stable operation of the power system is ensured by uninterrupted, reliable and high-quality power transmission, as well as emergency automation and relay protection. The main purpose of relay protection is to ensure selective tripping of the fault and to limit its negative effects. The relay protection devices are designed to detect sudden deviations of the power system parameters from the allowable levels and to implement a control action that prevents fixed parameter deviations.

The management of emergency modes must ensure the following tasks:

• prevent malfunctioning of power systems, • interrupt this mode to protect consumers and cells from the adverse effects of short circuits, and • prevent unacceptable deviations in voltage and current values.

Analysis of prior art

Different principles and protections are used to identify a malfunction or abnormal operating mode, such as distance protection; differential protection; maximum, zero-current, overcurrent protection, etc. Usually, the protections are combined in one device and implemented as separate functions in it [1-3]. With the advancement of information exchange technologies, defenses became able to communicate effectively and securely with each other and with dispatch centers [4-6]. However, the liberalization of the electricity market is encouraging the development of a new type of connection. Substation schemes require relatively large capital investments, but new entrants want to be competitive and cheaper to connect to the 110 kV network. The result is a contradiction between safety and cost-effectiveness. To meet this challenge, it is imperative to change the ideology of relay protection by offering solutions based on efficient use of communication channels and implementation of non-standard solutions.

At the heart of new technologies are advanced communication tools and their security, as well as the ability to quickly and efficiently identify and prevent communication failures [7, 8]. Currently, there are a number of data transmission protocols and principles that allow secure and effective remote control and availability control [9, 10].

The remote protection device GRZ100 and its method of operation described on the Internet site [11] have been adopted as a prototype of the invention. The madness of the prototype device and technique is that the protection does not provide the necessary selectivity and speed in the event of a loss of communication system or master (English) capability. As a result, protection cannot work accurately to localize the damage and its consequences.

The wiring diagram of the prototype device is shown in Figure 3 and the principle of time correction is shown in Figure 4. The disadvantage of this device is that it is not possible to coordinate the relay protection operation in the absence of communication channels, ensuring timely failure shutdown. As a result, the selectivity and accuracy of the prototype device is inadequate in the event of loss of communication channels or master. The information is exchanged using the communication channels and the corresponding time correction (Fig. 1), which observes the time delay of the communication channel (s) [11], which is calculated using the following formulas:

T _M = Τ _ά1 -ΔΤ, (1) A ⁼ A2 + ΔΤ, (2) A ⁺ Al ^_ Аг _л 5 (3)

where:

T _M is the time difference between the time of measurement of the master device and the moment of measurement by the master,

T _F is the time difference between the time of measurement of the slave and the moment of measurement from the slave,

T _dx and T _d2 are the time delay of the communication channel in each direction,

ΔΤ is the time difference between measurements.

One device is selected as the time reference and master. Other devices are selected to be controlled (from Slave). The master and slave are selected for synchronization of measurement time only. The time Tm is recorded in the master device and then sent to the master device along with the existing data where the ΔΤ value is calculated. As a result, the controlled device corrects its measurement time to the value of ΔΤ, calculated using formula (3), reducing the measurement time error between devices to zero. When device "A" (Fig. 3) is selected as the lead, the synchronization control takes place between devices "A" and "B" and devices "B" and "C". Thus, device "B" follows device "A" and device "C" follows device "B" (Fig. 3). The operating conditions are realized using the measurements of current transformers and sprinklers and the corresponding settings (Fig. 5) [11].

Communication channel (s) performance testing facilities already exist [12], but are mainly used for routine inspection or repair rather than for real-mode control.

The prototype device for the protected line ensures data synchronization at all terminals simultaneously. Data synchronization does not require external reference clocks or internal clock synchronization at relay protection terminals. The data synchronization error shall not exceed ± 10 ps between two terminals and shall be within ± 20 ps for three terminals. Data synchronization is accomplished through time synchronization management and data address synchronization management. This type of synchronization is performed by the devices each cycle [11]. In fact, the leading Master device provides a time reference point for other devices. The disadvantage of this technique and device is the inability to provide far-reaching bookings with allowable speed and selectivity for short circuits occurring on the lower voltage buses (Fig. 2) in the event of loss of master device or communication channels.

The prior art is illustrated by the following drawings:

Figure 1 shows a fragment of a grid of a power system, wherein: 1 is a bus 1 with a voltage U i and an angle φ _χ ; 2 is the 2 bus with voltage U2 and angle φ ₂ ; 3 is the transmission line; 4 is a generator (system) connected to bus 1; 5 is a generator (system) connected to bus 2; 6 are power switches;

Figure 2 shows a fragment of a high voltage and distribution network, wherein: A and В are high voltage buses; C is the medium voltage bus; The short is a short circuit, 1 is a transformer that connects the high voltage and distribution network; 2 are high voltage circuit breakers; 3 is a medium voltage power switch; 4 is the local generation of the distribution network;

Figure 3 is a diagram showing three prototype devices, wherein: A is the master device ·, В and C are the slave devices ·, CH1 and CH2 are the outputs and inputs of the first and second communication channels; 1 is the communication channel between devices; 2 is a communication port for transmitting information between devices В and C;

Figure 4 illustrates the principle of time synchronization between master and slave;

Figure 5 illustrates the current operation of the device "С" protection.

Purpose and substance of the invention

The object of the invention is to overcome the disadvantages of the prototype. To achieve this, in addition to basic protection, the proposed test device (block) is used to monitor the working condition of the communication channel (s) and local protection (Fig. 6) and to operate in case of loss of remote communication channels and / or local protection failure. Known communication device (s) performance testing equipment [12], which is primarily used in routine inspections or repairs, is used in a particular case for purposes other than real-time control. The Global Positioning System (GPS) satellite synchronization pulses or the delay of the communication channel (s) are used for data synchronization. It should be noted that communication channels are an integral part of the power system and have specific requirements (performance, high security and throughput, external penetration protection and malicious interference) that must be met. The main advantage of the device and the method according to the invention is that it is simpler and more economical to connect it to a high-voltage network, providing the necessary selectivity and speed through communication channels and their known test devices. In case of loss of communication with remote devices "A" and "B", a control pulse is applied to disengage the circuit breaker. The reliability of the communication system can be increased by additionally using the principle of reserving elements (duplication of communication channels).

The invention is explained by the following drawings:

Figure 6 illustrates a method of realizing an electrical network protection device with a relay protection device and a test device, wherein: 1 are communication channels between the devices А, В and C; 2 has the element "OR"; 3 has a power switch, and

7 illustrates the basic structure of a protective device according to the invention, wherein: 1 and 2 are communication channels between the remote relay protection devices and the test device; 3 is a local communication channel with a relay protection device; 4 is an input-output signal unit; 5 is a processor that provides information processing according to the implemented algorithm; 6 is an actuator block that provides a tripping impulse; 7 is an "OR" element.

Example of implementation of the invention (Fig. 6)

The test equipment monitors the working condition of the communication channels from remote devices ("A" and "B") and controlled devices (local devices "C"). Voltages are supplied to the input of each device • ·

U and currents I. The times of these measurements are synchronized by GPS or by any other synchronization technique. Measurements are transmitted between devices using communication channels (1). The test equipment shall monitor the performance of the communication system and of the equipment under control ("C"). In the event of a fault in the communication system or loss of the controlled device ("C"), the device supplies a pulse to the "OR" unit (2) which provides a command to the power switch (3). If the tester is lost, the protection device "C" sends a command to the "OR" unit (2) which triggers the circuit breaker (3).

Used information sources:

1. SEL-311C Transmission Protection System; https://www.selinc.com/SEL-311С/ (Dec 18, 2015)

2. GR and N Series Relay;

https://www.toshiba. co.jp/sis/en/tands/protect/f_p_rly.htm (Dec 18, 2015)

3. GE Transmission Protection Products; http://www.gegridsolutions.com/multilin/catalog/transmission.htm (Dec 18, 2015)

4. SPA-ZC 402 - Ethernet & IEC 61850 Adapter; http://new.abb.com/medium-voltage/distribution-automation/communication- devices / communication-modules-and-adapters / communication-adapter-spa-zc-402 (Dec 18, 2015)

5. ABB Power System and Distribution;

http: // new. abb.com/power-transmission (Dec 18, 2015)

6. LEK055. Maintenance of generators, generator - transformer units, 110 kV and 330 kV lines, buses, transformer relays protection and automation, Latvian Association of Electrical Power and Power Constructors, 03.01.2005, 49 p.

7. LEK106. Use of ISDN Protocols, Latvian Association of Power Generators and Power Builders, 21.06.2004, 31 pages.

8. LEK093, Telecommunication Optical Cable Lines. Main Technical Requirements, Latvian Association of Power Generators and Power Builders, 25.09.2006, 15 pages.

9. LEK124. Microwave Radio Relay Lines, Latvian Association of Electric Power and Power Builders, 21.06.2004, 40 pages.

10. Selecting and Using RS-232, RS-422, and RS-485 Serial Data Standards; https://www.maximintegrated.com/en/app-notes/index.mvp/id/723 (Dec 21, 2015)

11. Toshiba GRZ100 Distance Protection Device; https://www.toshiba.co.jp/sis/en/tands/protect/grll 00.htm (Dec 18, 2015)

12. Communication channel testing equipment; http://www.moctkom.ru/products/etest/etstugru.htm (Dec 27, 2016)

Claims (2)

Claims 1. An electrical network relay protection device comprising a relay protection unit, a communication channel input and output, an actuator unit and a processor, characterized in that it further comprises a test device for controlling a communication channel from remote devices and a local controlled device which inputs - an output signal unit to which the local and remote communication channels are connected, as well as a processor and output unit which provides control pulse to the specified switching device in case of failure of the local relay protection device and / or communication channels. An electrical relay protection method implemented by the device according to claim 1, the method comprising the steps of: - control of signals coming from local and remote communication channels, - processing and analyzing said signals in said test device, - controlling the communication channel and the capability of said local device in the test device and sending an appropriate command to the "OR" unit providing - sending a control pulse to the specified switching apparatus for disengaging the circuit breaker.