RU108233U1 - DEVICE FOR REDUCING CURRENT RISES WHEN TURNING ON THE TRANSFORMER - Google Patents

Abstract

 A device for reducing inrush currents when a transformer is turned on, containing a switch connected to the mains supply, a switch control system, a voltage transformer connected to a transformer synchronous switching device containing a synchronization unit with a voltage in the network, a switch-on moment setting switch, a control signal generator, a first converter contact signals to logic, the input of which is connected to the normally open block contact of the switch, and the output is connected via the second logical element "I" with a short circuit connected to the coil of the drive to turn on the circuit breaker, the second contact signal to logic converter, the input of which is connected to a normally closed block contact of the switch, and the output is connected through the second logical element "And" to another short circuit connected to the circuit breaker drive coil, characterized in that it further comprises a memory device for the moment the circuit breaker is tripped, the third and fourth converters of contact signals to a log logical, while the first input of the storage device is connected to the synchronization unit with the mains voltage, the second input is connected to the output of the second logical element “AND”, and the output is connected to the setting unit for the moment the switch is turned on, the input of the third contact signal to logic converter is connected to the signal terminal to turn on from the control system of the switch, and the output is connected to the first logical element "AND", the input of the fourth converter of contact signals into logic is connected to the terminal for the signal to disconnect from

Description

The utility model relates to the field of electrical engineering, and can be used to reduce inrush currents when turning on transformers, mainly traction in railway transport.

A device is known for eliminating inrush currents when switching on network transformers, comprising a current-limiting resistor connected in series with the primary winding of the transformer, a switching element connected in parallel with the resistor, and a control element for the switching element (AS USSR No. 1269755, class N02H 9/02, 1986 )

The disadvantage of this device is the complex connection diagram of the transformer. The need for additional costs for special equipment leads to the inappropriateness of its use in existing traction substations.

A device is known for protecting a three-phase transformer against inrush currents, comprising a unit that sets the intrinsic time of operation of the circuit breaker, a synchronization unit, a delay unit and an AND logic element, the first input of which is connected to the output of the delay unit, the second input is connected to the output of the contact block, generating and giving the signal “inclusion”, the third input is connected to the control unit of the state of the poles of the vacuum circuit breaker, and the output of the logic element “And” is connected to the input of the drive control system floor owls, the output of the synchronization unit is connected to a first input of delay unit (Russian patent for utility model №97223, Cl. N02N 9 / 02,2010).

This device has a rather complex design, including redundant functional elements, in particular, a set of single-phase measuring transformers, modules for calculating residual induction, measuring transducers, the presence of which entails significant additional costs that are unnecessary for problems solved at existing traction substations of railway transport.

A device is known for implementing a method of reducing switching currents during multiple switching of a transformer (RF patent for the invention No. 2093943, class N02H 9/02, 1997), comprising an operational switch, a control panel for the switch, a voltage transformer connected to a switch synchronization device connected to the mains comprising a synchronization unit with a voltage in the network, a unit for setting the moment of opening the circuit breaker, a unit for setting the moment of turning on the circuit breaker, control signal conditioners, For contact signals to logic, one input of which is connected to the normally closed block contact of the circuit breaker, the second input is connected to the terminal for the signal to disconnect from the control panel of the circuit breaker, and the outputs are connected via logic element AND to a short circuit connected to the coil of the circuit breaker drive, and also a second converter of contact signals into logical ones, one input of which is connected to a normally open block contact of the switch, the second input is connected to a terminal for a signal for switching on from the control unit switch, and the outputs are connected through the AND gate to another short circuit connected to another coil of the circuit breaker trip drive.

The known method allows to increase the reliability of transformers, switching and protective equipment by reducing electrodynamic forces and switching overvoltages. However, the device for its implementation provides means for a time delay when the transformer is disconnected from the network. Such a technical solution during a short circuit on the equipment leads to more serious damage due to the inability to instantly turn off the transformer.

As a rule, in traction substations, one (main) converting unit, consisting of a traction transformer and a rectifier, must be constantly in operation, and the second (backup) should be connected for a while to increase the traction load, followed by shutdown. In this mode, at the moments of connecting the backup traction transformer, current surges are often observed, leading to voltage dips, which, in turn, lead to serious malfunctions in the microprocessor and other equipment of non-traction consumer devices, complicate the setting and operation of relay protection; reduce equipment life and train safety. Therefore, often in order to prevent possible risks of equipment malfunctions, at the traction substations they are constantly forced to keep both traction transformers in non-switchable mode, which is associated with additional energy losses.

Inrush current surges, with an unfavorable combination of residual inductions in the rods and the inclusion phase, can reach large values of the order of 5 I _NOM or more. The synchronous transformer switching device, which is part of the proposed utility model, allows you to remember the shutdown phase and turn it on exactly in the same phase. This ensures that the area of the induction sine wave, which turns out to be higher than the saturation region in the first switching period, practically tends to zero, therefore, the value of the switching current in such cases does not exceed the value of the rated current for the transformer

I _ON ≤I _NOM .

The proposed utility model solves the problem of reducing the operating time of the backup converter unit by ensuring stabilization of the power supply parameters and increasing quality indicators of the voltage supplying the electronic and microprocessor equipment.

The technical result is to increase the reliability of electrical equipment by instantly disconnecting from the network when the power parameters reach critical values.

The indicated result is achieved in that the device for protecting the transformer from inrush currents contains a switch connected to the mains supply, a control system for the switch, a voltage transformer connected to a device for synchronously turning on the transformer. The latter contains a synchronization unit with the mains voltage, a unit for setting the moment of turning on the switch, a driver of control signals, a first converter of contact signals to logic, the input of which is connected to a normally open block contact of the switch, and the output is connected through the first logical element "I" with a short circuit connected with a drive circuit breaker drive, a second converter of contact signals into logic, the input of which is connected to a normally closed block contact of the switch, and the output d is connected through a second gate "AND" short-circuiting with the other connected to the drive coil of the circuit breaker.

A distinctive feature of the claimed device is that it additionally contains a memory device for turning off the circuit breaker, third and fourth converters of contact signals to logic, while the first input of the storage device is connected to the synchronization unit with the mains voltage, the second input is connected to the output of the second logical element "AND ”, And the output - with the unit for setting the moment the switch is turned off, the input of the third converter of contact signals into logic is connected to the terminal for the signal for switching on from the control system of the circuit breaker, and the output is connected to the first logical element “AND”, the input of the fourth converter of contact signals into logical ones is connected to the terminal for the signal to disconnect from the control system of the circuit breaker, and the output is connected to the second logical element “AND”.

With this embodiment of the device, it is possible to turn off the equipment without a time delay (at any time), due to the fact that the device remembers at what point in time, counted from the beginning of the period of increasing voltage of the network in one of its phases, a trip occurred, and the circuit breaker contacts when the next connection of the transformer to the network is made at the same time, measured from the same as in the previous shutdown, the beginning of the period of increase in voltage in the same phase of the network.

The device proposed in accordance with the utility model, with small changes in the circuit, can be used to reduce inrush currents not only in three-phase, but also in single-phase and any multiphase networks.

The drawing shows a block-modular diagram of a device for reducing inrush current when the transformer is turned on.

In an example embodiment of the device, it was connected to traction three-phase transformers of the TRDP-12500/10 type installed to supply the traction load through the rectifier unit at the traction substations of the West Siberian Railway.

The device contains a vacuum circuit breaker 2 connected to the supply network 1, connected through a traction transformer 3 to a rectifier 4. A voltage transformer 5 and a synchronous switching device 6 of the transformer 3, electrically connected to the voltage transformer 5 and the control system 7 of the switch, are also connected to the supply network, signals switching on and off to which come from operational control circuits, telemechanics, relay protection and automation of the converter unit.

The switch 2 contains a coil 8, 9 of the drive, respectively, turning on and off the switch; as well as a normally open block contact 10 and a normally closed block contact 11.

The transformer synchronous switching device 6 comprises a synchronization unit 12 with a mains voltage connected to the first input of the storage device 13 and the first input of the control signal shaper 14. The output of the storage device 13 is connected to the input of the switch-on moment setting unit 15, the output of which is connected to the second input of the signal shaper management 14.

The output of the shaper control signals 14 is connected to the first input of the logical element "And" 16, the output of which is connected to the input of the short circuit 17, connected to the coil 8 of the drive actuator switch 2.

The second input of the AND gate 16 is connected to the output of the contact signal to logic converter 18, to which a normally open block contact 10 of the switch 2 is connected. The normally closed contact 11 of this switch is connected to the contact signal to logic converter 19, the output of which is connected to the input the logical element "And" 20, connected to the short circuit 21 and the second input of the storage device 13. The short circuit 21 is connected to the coil 9 of the drive shut-off switch 2.

The terminal (not indicated) of the enable signal from the control system 7 is electrically connected to the converter 22 of the contact signals into logic, the output of which is connected to the input of the logical element "And" 16.

The terminal (not indicated) of the shutdown signal from the control system 7 is electrically connected to the converter 23 of the contact signals into logic, the output of which is connected to the input of the logical element "And" 20.

The device operates to reduce inrush current when the transformer is turned on as follows.

To prepare the device for operation, the temporary characteristics of the vacuum circuit breaker 2 are taken, since each switch has its own on and off time. For maximum effect, the switch must have stable intrinsic on and off times, which are programmed into the device 6 for synchronous switching on of the transformer. The range of the own times of the circuit breaker should not exceed 2 ms.

Each subsequent inclusion of the transformer 3 by the switch 2 is carried out through the device 6 synchronous inclusion of the transformer. To do this, the signal from the control system 7 is supplied to the contact signal converter 22 and the contact signal converter to the logic 18 is supplied with a signal on the position of the switch from the normally open block contact 10. From the converters 22 and 18, the signals are fed to the logical element “AND” 16, and he gives the command to turn on only when a signal arrives at him from the shaper of control signals 14. Information on the moment of shutdown from the storage device 13 is received in block 15 for setting the moment the switch is turned on. settings in the range of 20 ms (360 degrees) forms a time delay so that, taking into account the intrinsic response time of switch 2, the contact closure occurs at the same moment relative to the sinusoid of the reference voltage U _A as during a trip, which is counted from the same as in the previous trip, the beginning of the period of voltage change with a positive derivative. This information is fed to a signal shaper 14, which supplies a control signal to the logic element “I” 16, which, in the presence of confirming signals from the converters 22 and 18, allows the passage of the switching command to the short circuit 17 to operate the coil 8 of the circuit breaker drive. When switch 2 is ready (controlled by its block contact 10) and there is a command to turn it off, short circuit 17 connects a DC voltage of 110 V to coil 8 and switches 2 on.

Each subsequent shutdown of the transformer 3 by the switch 2 is carried out through the device 6 synchronous inclusion of the transformer. To do this, a signal from the control system 7 is supplied to the converter 23 of the contact signals to the logic, and a signal about the position of the switch from the normally closed block contact 11 is fed to the contact signals to the converter 19 from the converters 23, 19, the signals are fed to the logical element "AND" 20, which allows the passage of the trip command to the short circuit 21 to operate the coil 9 of the drive circuit breaker. When switch 2 is ready (it is controlled by its normally closed block contact 11) and there is a command to turn it off, short circuit 21 connects a DC voltage of 110 V to coil 9 and instantly switches circuit breaker 2 off.

The moment of passage of the command to the coil 9 of the shutdown drive is remembered using the device 13. This moment, taking into account the intrinsic response time of the switch 2, is always counted from the moment the voltage sine wave passes through zero with increasing voltage, that is, with a positive derivative. To do this, the reference voltage of phase A (U _A ) from the voltage transformer 5 is introduced into the synchronization unit 12 with the mains voltage, from which this voltage is supplied to the storage device 13 and to the control signal generator 14.

It was experimentally established that without the use of the proposed device, the maximum inrush currents were 4.2-4.7 kA, which corresponds to a five-fold value of the rated current for the transformer. When using the device, the maximum inrush current is reduced to 1 kA.

Claims (1)

A device for reducing inrush currents when a transformer is turned on, containing a switch connected to the mains supply, a switch control system, a voltage transformer connected to a transformer synchronous switching device containing a synchronization unit with a voltage in the network, a switch-on moment setting switch, a control signal generator, a first converter contact signals to logic, the input of which is connected to the normally open block contact of the switch, and the output is connected via the second logical element "I" with a short circuit connected to the coil of the drive to turn on the circuit breaker, the second contact signal to logic converter, the input of which is connected to a normally closed block contact of the circuit breaker, and the output is connected via the second logical element "And" to another short circuit connected to the circuit breaker drive coil, characterized in that it further comprises a memory device for the moment the circuit breaker is tripped, the third and fourth converters of contact signals to a log logical, while the first input of the storage device is connected to the synchronization unit with the mains voltage, the second input is connected to the output of the second logical element “AND”, and the output is connected to the unit for setting the moment the switch is turned on, the input of the third contact signal to logic converter is connected to the signal terminal to turn on from the control system of the switch, and the output is connected to the first logical element "AND", the input of the fourth converter of contact signals into logic is connected to the terminal for the signal to disconnect from Istemi control switch, and an output connected to the second gate "AND".