UA69607A - Mine transformer substation - Google Patents

Abstract

The proposed mine transformer substation contains a step-down power transformer, a disconnector and a circuit-breaker in the high-voltage circuit, disconnectors and load circuit breakers in the low-voltage circuits, a unit for protection against short circuits and earth currents, a unit for testing insulation, a logic control unit, a bus disconnector, an earth disconnector, and voltage and power indicators. The input of the logic control unit is connected to the output of the unit for protection against short circuits and earth currents, and the outputs are connected to the control inputs of the corresponding load circuit breakers. The control inputs of the circuit breaker in the high-voltage circuit are connected accordingly to the output of output of the unit for protection against short circuits and earth currents and the output of the unit for testing insulation. To each load circuit breaker, a unit for compensating reactive power and a unit for testing insulation in the load circuit are connected.

Description

Description of the invention

The proposed technical solution belongs to electrical engineering, in particular, mine (mine) 2 transformer substations and can be used to supply electricity consumers in areas of coal mines, mainly dangerous due to gas and dust explosions.

A mine transformer substation is known, comprising a main circuit equipped with a high voltage disconnector, a circuit breaker and a transformer, and in the circuit breaker control and interlock circuit it has a programmable tripping system connected to a device for protection against leaks and a system of disconnectors 70 of the circuit breaker higher voltage, and on the lower voltage side, power current circuits have terminals, each of which is equipped with maximum current protection and protection against asymmetric operating modes, fuses and safety disconnectors (see Polish patent Mo118752, НО2В 13/00, НО2В 11/ 24, published on November 30, 1982)

When an earth fault occurs on one of the outgoing connections, the device for monitoring the condition of the network isolation sends a signal to the switchgear. Moreover, if the short circuit is eliminated, then after its 72 disappearance, the connection is automatically connected to the power source. In the event of a short-circuit to the ground on one of the connections, the switchgear disconnects the damaged connection and its reconnection is carried out by the service personnel after finding and eliminating the damage.

The main disadvantage of this technical solution is that when one of the connections is shorted to the ground, the device for protection against current leaks is triggered and the main circuit breaker (higher voltage) is turned off, which leads to the disconnection of all current receivers, even those that cannot be disconnected by the conditions explosion protection, for example, local ventilation fans (VMP), control and protection devices. During the search and elimination of the malfunction, the indicated current receivers will be disconnected. Meanwhile, when the VMP is turned off, gassing of the product occurs, which poses a danger of methane explosion or suffocation of people. In addition, the specified solution does not provide compensation for network capacity, which is required by DOST 22929 "Apparatus to protect against leakage currents for networks up to 12008". "

Also known is a mine transformer substation, which contains a power step-down transformer, a disconnector or switch in the high-voltage circuit, disconnectors and switches in the connection circuit, devices for protection against short-circuit currents and against current leakage to the ground, a logic block, the input of which is connected to the output of the protection device against current leakage to the ground, and each of the outputs is connected to the circuit of disconnecting switches - load, each load switch is equipped with a compensation device connected to its output Ha») capacity and a device for preliminary control of insulation, while the number of outputs of the block of logic corresponds to the number of load switches. In addition, the input of one of the load switches is connected to the output of the other load switch, and each of the outputs to the load is connected to the output of the corresponding switch (see decision no. 21.08.03 on application Mo2003010781, E21NZ/17).

Currently, as operational experience has shown, in the power supply systems of mines, especially those that develop coal seams on several horizons in several sections, there is a need to supply high voltage power from the mine mobile transformer substation installed on one of the horizons to the substation, installed on another horizon (in another place or another product). However, well-known substations cannot implement this function, because they do not have an output from the high voltage side, equipped with the necessary electrical devices and protections that meet safety requirements. Therefore, it is necessary to supply power to each mobile transformer substation installed on different horizons (in different

With" places), separate cables from complete distribution devices installed in stationary substations or high-voltage distribution points. At the same time, a significant amount of high-voltage cables is consumed, and operational and safety conditions deteriorate.

In addition, a number of accidents with mobile transformer substations were noted at the mines, which were caused by short arcs occurring in the output circuits of power (se) transformers. With such circuits, the current k. z. limited by the resistance in the electric arc, as a result of which devices for protection against currents complete distribution devices cannot work, the transformer b of the substation works in the mode of a large overload, which leads to the failure of its windings, and av! 20, the electric arc burns the explosion-proof shell of the substation and breaks its explosion protection, which leads to the danger of an explosion of the methane-air environment or to a fire. This must be attributed to the shortcoming of the known transformer substation, identified as a prototype.

The basis of the invention is the task of creating a mine transformer substation, in which, due to a new schematic solution, the possibility of powering substations installed on other horizons (in 29 other places) or cable lines of electricity supply to consumers of other horizons is ensured, as well as prevention of dangerous overloading of power transformers in the mobile substations themselves.

The task is solved due to the fact that in the mine transformer substation, which contains a step-down transformer, a disconnector in the circuit of higher voltage, disconnectors and switches in the circuit of connections of lower voltage, devices for protection against short-circuit currents and against current leaks to the ground, the logic block, the input of which is connected to the output of the current leakage protection device, and each of the outputs is connected to the tripping circuit of the load switches, each load switch is equipped with capacity compensation devices and insulation preliminary control devices connected to its output, according to the invention , it is equipped with at least one output in the high-voltage circuit, which includes a switch, short-circuit protection units, earth-fault current protection devices and a preliminary insulation control device, the outputs of which are connected to the tripping circuit of the circuit breaker, as well as a bus disconnector and output linear disconnector-earther, voltage and load indicators.

In addition, the higher voltage circuit of the power transformer is equipped with an overload protection unit, for example, a circuit breaker with a protection device that has a current-time characteristic or fuses.

Figure 1 shows the scheme of the proposed substation with a circuit breaker in the higher voltage circuit of the transformer; Figure 2 shows a diagram of a substation using fuses as protection against overloads.

The substation contains a three-phase power transformer 1, located in an explosion-proof shell 2. On the higher voltage side, the substation is equipped with a cable entry from the high-voltage switchgear (RPVN) and a disconnector 4, located in an explosion-proof shell 5. 70 On the lower voltage side, the transformer is equipped with several for example, by two terminals I and II, feeding two lower voltage switchgears (switchgear), respectively.

In the explosion-proof shell of terminal 6 of terminal I, to which the first transformer is connected, there are a disconnector 7, a circuit breaker 8, current transformers 9, a device 10 for protection against current leaks, a transformer 11 of its own needs, measuring devices (voltmeters and ammeters) 12, a block logic 13, outputs 14 and 15 of block /5 LOGIC, block 16 of preliminary control of insulation and device 17 of capacity compensation. The lead to the load is placed in an explosion-proof casing 18.

In the explosion-proof shell 19 of the II terminal, to which the second transformer is connected, are placed: disconnector 20, automatic switch 21, current transformers 22, measuring devices (voltmeters, ammeters) 23, transformer 24 of own needs, block 25 of preliminary control of insulation, device 26 capacity compensation.

The output to the load is placed in an explosion-proof shell 27. The device 10 for protection against current leakage to the ground is located in an explosion-proof shell 28.

All elements of the bkV output circuit: switch 29 with a protection unit 30 against short-circuit currents and current leakage (short-circuits) to the ground, insulation preliminary control unit 31, output line disconnector-earther 32, bus disconnector 33, voltage transformer 34, fuses 35, placed in an explosion-proof casing in Zb with cable outlet 37, unit 38 of protection against overload of the power transformer (switch with current-time protection), or fuses placed in casing 5.

The proposed substation works as follows.

The three-phase voltage bkV through the cable enters the cable entry compartment 3, and then through the pass-through electrical clamps to the three-phase disconnector 4 and the overload protection unit 38, which are located in the M zo shell of the RPVN 5, and then through the pass-through clamps to the transformer 1, is located in the shell 2, as well as on the bus disconnector 33, the switch 29 with protection elements and the linear disconnector 32. The three-phase voltage (380, 660 o or 11408) from the secondary winding of the transformer 1 is supplied through the pass-through terminals to the inputs of the three-phase Ge roz connectors 7 and 20, switches 8 and 21 and device 10 to protect against current leakage to the ground. From the outputs of switches 8 and 21, three-phase voltage enters the explosion-proof compartments of terminals 18 and 27, respectively, and further - (22)

Зз5 before loading. Transformers 11 and 24, as well as current transformers 9 and 22 (in each phase or in 2 phases), are used to power the auxiliary circuits and short-circuit current protection units (not shown in figures 1 and 2). electrical measuring devices 12 and 23.

To one of the terminals, for example, II, current receivers are connected, which are prioritized in terms of uninterrupted power supply, for example, VMP of dead-end production. "

The output of the device 10 is connected to the input of the block 13, the output 14 of which is inserted into the disconnection circuit of the switch 8 of the first RPNN, and the output 15 of the disconnection circuit of the switch 21 of the second RNPN. Logic block 13 provides priority. disconnection of switches 8 and 21 in such a way that in the case of damage to the insulation and leakage of current to the ground in the connections, which are outgoing, the priority connection will not be disconnected first, but the priority connection will not disconnect if it is not damaged (leakage of current to the ground).

To ensure capacity compensation, blocks 17 and 26 are provided, the input terminals of which are connected to the output

Ge» terminals of switches 8 and 21. In the event of damage to the insulation in any of the outgoing connections, the device 10 for protection against current leaks is triggered and sends a signal to the logic block 13. The signal from the output of this block ik enters the disconnection system of switches 8 and 21, which are triggered according to priority. In disabled

In the state of the corresponding switch, the insulation resistance of its outgoing electric circuit is monitored by blocks 16 and 25. If the insulation resistance on one of the connections does not meet the norm, the corresponding switch is blocked (prohibition) from turning on. At the same time, the priority switch does not activate and is not blocked,

And what ensures uninterrupted power supply of current receivers.

If the current leakage occurred in the circuit of the priority UPS, then both switches 8 and 21 are turned off.

Devices 17 and 26 provide compensation for capacitive leakage currents occurring in the network. Each of these devices is configured according to the capacity of the network section connected to this output.

In the capacity compensator scheme, a zero point created by three capacitors connected is used

P star, between the zero point of which and the ground, a compensating inductance is connected. This allows for compensation not only in the applied voltage mode, but also when the voltage is disconnected, and the leakage current is created due to the EMF of electric motors (loads) rotating by inertia. In the scheme of blocks 16 and 25 for preliminary control of insulation, their disconnection is provided when switches 8 and 21 are turned on, for example, by inserting the opening block contacts of the corresponding switch into their circuit.

In the event of an arcing short circuit at the output of transformer 1 or another mode that caused it to overload, the overload protection of unit 38 will activate and power to transformer 1 will stop.

A cable feeding the substation, which is installed on another 65 horizon (in another place), is connected to the output in the circuit of a higher voltage of 6 kV. If it is necessary to connect a substation installed nearby, a free cable entry 3 can be used. Disconnection of the kV output is done by the switch 30 from the local control panel or remotely, for example, by the mine dispatcher using the "VETER" equipment (not shown on the diagrams) or automatically at the expense of activation of protection devices. Signaling about voltage and load is carried out with the help of indicators available in the diagram (not shown in the diagrams). All circuits of own needs are powered by voltage transformer 34. Disconnectors 4, 32, 33 are used to meet safety requirements during maintenance.

The use of the proposed mine transformer substation will improve the safety of mining operations, as well as ensure the saving of high-voltage cables and implement modern operation requirements for power supply of mine electrical equipment and mining machines. 5 GA b her 1 Iv and. 1 7 Fe vve -Y che; pIrevee JSC

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Claims (1)

The formula of the invention of 1. Mine transformer substation, containing a power step-down transformer, a disconnector in the high voltage circuit, disconnectors and switches in the circuit of lower voltage connections, devices for protection against short-circuit currents and current leakage to the ground, a logic block , the input of which is connected to the output of the current leakage protection device, and each of the outputs is connected to the disconnection circuit of the load switches, each (Se) load switch is equipped with capacity compensation devices and preliminary insulation control connected to its output, which is distinguished by the fact that its equipped with at least one output in a high-voltage circuit containing a circuit breaker, short-circuit protection units, earth-fault current protection devices and a device for preliminary "insulation control", the outputs of which are connected to the tripping circuit of the circuit-breaker, as well as a bus disconnector and an output line disconnector grounding connector, voltage and load indicators. t s 2. Mine transformer substation according to claim 1, which differs in that the higher voltage circuit of the power "" transformer is equipped with an overload protection unit, for example, a switch with a protection device that " has a current-time characteristic, or fuses. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated (22) microcircuits", 2004, M 9, 15.09.2004. State Department of Intellectual Property of the Ministry of Education and Social Science of Ukraine. (o) («c) that 60 b5