RU109929U1 - RESERVE SYSTEM OF TRANSFORMERS OF RESPONSE SUBSTATIONS WITH DETERMINATION OF DAMAGED OBJECT AND TYPE OF DAMAGE - Google Patents

Abstract

 A backup protection system for branch transformers with identification of a damaged object and type of damage, consisting of long-range backup protection devices using information about line currents and voltages or only currents, characterized in that the power substation units including long-distance backup devices are introduced, the first and second output elements, first transceivers of supply substation blocks, second transceivers of branch substation blocks, switching equipment sensors a communication channel providing the connection of the first and second transceivers, the first output of the long-range backup device is connected to the input of the first output element of the power substation unit, acting to disconnect the power line, the second output of the long-range protection device is connected to the input of the second output element of the power substation unit, signaling about the type and area of damage, the third output of the long-range backup protection device acts to prohibit automatic restart power lines, the fourth input / output of the long-range protection device is connected to the input of the first transceiver, the first input / output of the short-range protection device of the branch substation unit is connected to the first input of the second transceiver, which uses information about the currents and voltages of connecting the branch substation, with the second input of the second the transceiver is connected to the output of the intermediate relay block branch substation, acting in the circuit off branch

Description

The inventive device relates to electrical engineering and can be used for relay protection of radial and transit overhead lines and cable lines having branches with transformer substations.

Known cabinet remote and current protection line type SHE 2607 021 [Operation manual ECRA. 656453.049 OM], which consists of a line protection terminal that can perform the functions of long-distance backup, high-frequency television disconnect signal transceivers, output elements acting on shutdown and signaling, the cabinet can use a wired communication channel with high-frequency processing as part of the network relay protection system. The disadvantages of this device are: 1) the restriction of the use of signals overhead lines with high-frequency processing, which involves the installation of expensive high-frequency communication equipment; 2) the inability to determine which branch substation damage occurred if there are several branch substations; 3) devices of this type, as a rule, are insensitive to short circuits behind low-power transformers and in the absence of communication at these substations, their use is ineffective.

A known method of differential-phase protection of a power line [RF Patent 23 0743 7], which describes a technical solution consisting of two half-sets, each of which consists of a first receiver, a pulse synthesizer, a code generator, a transmitter, a code setting unit, a second receiver, a decoder , the first and second memory blocks, digital-to-analog converters and amplifiers with a transmitter. As a device for calculating and generating control commands, a microcomputer connected to the second receiver is used through an analog-to-digital converter unit. A communication channel is laid between the half-sets.

The disadvantage of the described technical solution is the use of a limited number of half-sets installed at the power substations, which, if there is a significant power flow through the power line (power transmission line), makes the detection of a short circuit (short circuit) behind the branch transformer transformer almost impossible.

The closest technical solution (prototype) is a backup line protection device with transformers on the branches [RF Patent No. 2162269], consisting of current sensors of all three phases of the line, the outputs of which are connected to the inputs of the reverse and forward sequence current filters, voltage sensors connected to the interphase voltages, the outputs of which are connected to the inputs of the direct sequence voltage filter, and its output is connected to the second input of the first phase comparison circuit, the output of which is connected to the seventh input of the block geek, the sixth input of which is connected to the output of the fifth module comparison circuit, the input of which is connected to the output of a zero-sequence current filter, the inputs of which are connected to the outputs of the current sensors, the outputs of one of the sensors and the negative sequence filter are connected to the inputs of the second and fourth current module comparison circuits, and their outputs are connected to the second and fourth inputs of the logic unit, the output of which is connected to the input of the output organ of the first and third comparison circuits of the modules, the inputs of which are connected to the current sensors from the phases and the reverse sequence current filter, and their outputs to the first and third inputs of the logic block, the second phase comparison circuit, the inputs of which are connected to the outputs of the reverse and direct sequence current filters, and the output with the fifth input of the logic block, the setpoint formation block, the outputs of which connected to the outputs of the current and reverse sequence current filters and the output of the second phase comparison circuit, and its output is connected to the additional input of the first phase comparison circuit. measuring current and voltage organs connected to phase currents and interphase voltages, respectively, module comparison circuits, phase comparison circuits, set point generation circuit, logic and time delay unit, and output organ.

The disadvantages of the described technical solution are the impossibility of determining the place of a short circuit at several branch substations on power transmission lines, on which transformers of comparable power are installed, the complexity of the detuning from load conditions during short-circuit behind low-power power transformers, for example, for an electric network of 110 kV for transformers with a power of 2.5- 4.0 MVA.

The objective of the utility model is to increase the sensitivity and selectivity of protection of long-distance backups by expanding the information base, simplifying the determination of a damaged object if there are several branch substations with transformers of comparable power on a high-voltage line, reducing the exposure time of a long-distance backup system by refusing to coordinate time settings with protections adjacent elements of the electric network, since the blocks of the power substation in the system exchange signals about triggering of measuring organs, determine which zone is the damage.

The technical result of the claimed utility model is that the backup protection system of transformers of branch substations with the definition of a damaged facility and the type of damage, consisting of supply substation units, including long-range backup protection devices using information about line currents and voltages or only currents, first output which is connected to the input of the first output element of the power substation unit, acting to disconnect the power line, the second output of the protection device you are connected to the input of the second output element of the power substation unit, indicating the type and zone of damage, the third output of the long-range protection device acts to prohibit the automatic restart of the power line, the first transceivers of the power substation blocks are introduced, the second transceivers of the branch substation blocks, switching sensors equipment, a communication channel for connecting the first and second transceivers, the fourth input / output the long-range backup protection device is connected to the input of the first transceiver, the first input / output of the protection device of the near redundancy of the branch substation unit is connected to the first input of the second transceiver, which uses information about the currents and voltages of connection of the branch substation, the output of the intermediate relay of the branch unit is connected to the second input of the second transceiver substation acting in the circuit of switching off the branch substation, with the third input of the second transceiver tchika coupled sensor output junction substation switchgear unit, an output of the third output member substation junction block is connected to the second output of the low redundancy protection device, and its output provides impacts on the branch switching devices substation. Branches of branch substations can be more than one, depending on the number of branch substations. There can be more than one power substation unit.

Figure 1 shows the placement of system blocks on the objects of the electric network. The above diagram shows a section of the electric network from one power line (L1) connecting four substations (Substation 1-Substation 4), where the substations Substation 3 and Substation 4 are branch substations with low power transformers (T1-T2). As switching equipment at PS 3, a separator (O1) and a short circuit (K1) are used, at PS 4 a full-fledged switch (B3) is used. As switching equipment at branch substations, both separators and short-circuiting devices, as well as load switches, full-fledged switches can be used. At branch substations, blocks of branch substations (BOPS _1- BOPS ₂ ) are installed according to the number of branches. In the above diagram, external electric power sources are connected to substations PS 1 and PS 2 in the form of equivalent systems C1 and C2, therefore, power substation units (BPS _1- BPS ₂ ) are installed at these substations. In addition, these substations are equipped with full-fledged switches B1, B2, acting to disconnect the line.

In figure 2. the structural diagram of the proposed device. The backup protection system of transformers contains blocks of power substations (BPS _1- BPS ₂ ) 1, each of which consists of a long-range backup protection device (UDR) 2, the first and second output elements (VE ₁ , VE ₂ ) 3, 4 and the first transceiver ( PP ₁ ) 5, branches of branch substations (BOPS _1- BOPS _n ) 6, each of which consists of a near backup protection device (UZBR) 7, an output element (VE ₃ ) 8, a second transceiver (PP ₂ ) 9, an intermediate relay ( RP) 10, sensor switching equipment (ATP) 11, communication channel (COP) 12.

The power substation unit (BTS) 1 performs the functions of a set of structural elements included in it: it detects damage at a remote substation, determines the damage zone based on its own measurements and information received from the branch substation units, can generate a signal to prohibit automatic restarting of the power line after shutdown. The long-range backup protection device (DDR) 2 detects a short circuit at the branch substation and then acts to turn off the power line circuit breaker, generates a signal about the damage zone, and can generate a signal to prohibit the automatic restart of the power line after shutdown. Output elements (VE ₁ -VE ₂ ) 3-4 convert the output signals of the long-distance relay protection relay device into the corresponding output signals of the relay protection system: form circuit breaker trips and alarm about the type and zone of damage.

The transceiver (PP ₁ ) 5 provides the coding of the signals of the long-range protection device and the decoding of the signals of the branch substation units, sends and receives encoded signals. Branches of a branch substation (BOPS) 6 perform the functions of a set of structural elements included in it: they identify damage at their own substation, collect information about damage and the condition of switching equipment at the substation. The near backup protection device (UZBR) 7 detects short circuits, out-of-phase modes, network short circuits at its own branch substation, acts on its switching devices, provides information about its status, as well as the status of switching devices, in the encoded signal. The output element (VE ₃ ) 8 converts the output signals of the near backup protection device into the corresponding output signal of the branch substation unit. The transceiver (PP ₂ ) 9 provides coding of the signals of the branch substation unit and decoding of the signals of the long-range backup protection device, sends and receives encoded signals. Intermediate relay (RP) 10 provides the formation of control circuits of switching devices of higher voltage branch substation. Sensor switching equipment (ATP) 11 changes the state of its contacts when changing the state of the switching equipment - on / off. The communication channel (CS) 12 is a medium for the distribution of encoded signals from one transceiver to another, for example, a radio channel, optical fiber, phase wires, etc.

In normal network operation mode, the described device is in the following state: the long-range backup protection device and the short-range protection device are in an unworked state, a logic 0 is present at the output of all output elements, the intermediate relay is in an unworked state, the signal at the output of the switching equipment sensor corresponds to an on state for separators and switches; and disconnected state for short circuit. Transceivers exchange test signals determining the presence of communication between protection devices.

In the event of a short circuit behind one of the transformers connected to the VL branch, the system operates as follows: the protection of the near redundancy of the substation where the short circuit occurs and the intermediate relay is activated accordingly. The long-range backup protection device, if it is sensitive to short-circuit, acts on the circuit breaker tripping. The near backup protection device sends information about the operation of its measuring organs to the transceiver. After the operation of at least one of the protection devices, a change in the state of the intermediate relay, the sensor of the switching equipment, the transceivers of the branch substation and the head exchange information about the operation of the protection devices, the state of the intermediate relay and sensors of the switching equipment. In this case, the long-range backup protection device receives information about the type of damage and the zone in which the short circuit has occurred and acts on the circuit breaker circuit breaker and alarm about the type and zone of damage.

In the case of a short-circuit “behind”, the blocks of power substations send a signal to adjacent blocks of power substations that the damage is not in the zone, which excludes the unselective effect of the long-range backup protections and allows them not to tune their time settings for protection from adjacent lines and sections.

Thus, the use of the proposed device can increase the sensitivity to short-circuit behind transformers of branch substations, since when the protection sensitivity of long-range backup is insufficient, it starts when a signal about the occurrence of short-circuit from the branch of the branch substation is received. In addition, at the supply substation, when damage occurs at one of the branch substations, the damage zone and its type are recorded, and an information signal is generated about the operation of switching devices at the branch substation, which can be used both to accelerate the protection of long-distance redundancy in the absence of a separator shutdown, so and for the implementation of adaptive ARs, etc.

Claims (1)

A backup protection system for branch transformers with identification of a damaged object and type of damage, consisting of long-distance backup protection devices using information about line currents and voltages or only currents, characterized in that the power substation units are included, including long-distance backup devices, the first and second output elements, first transceivers of supply substation units, second transceivers of branch substation units, switching equipment sensors communication channel, providing the connection of the first and second transceivers, the first output of the long-range backup device is connected to the input of the first output element of the power substation unit, acting to disconnect the power line, the second output of the long-range protection device is connected to the input of the second output element of the power substation unit, signaling about the type and zone of damage, the third output of the long-range backup protection device acts to prohibit automatic restart power lines, the fourth input / output of the long-range backup protection device is connected to the input of the first transceiver, the first input / output of the short-range protection device of the branch substation unit is connected to the first input of the second transceiver, which uses information about the currents and voltages of connecting the branch substation, with the second input of the second the transceiver is connected to the output of the intermediate relay block branch substation, acting in the circuit off branch tance, with the third input of the second transceiver, the output of the sensor of the switching equipment of the branch substation unit is connected, the output of the third output element of the branch substation unit is connected to the second output of the short-circuit protection device, and its output provides an impact on the switching devices of the branch substation, while the number of units of the supply substation is determined the number of supply substations, and the number of branches of branch substations is determined by the number of significant substations.