RU106753U1 - ZERO-CURRENT CURRENT FILTER BASED ON SINGLE-PHASE TRANSFORMER WITH A ROTATING MAGNETIC FIELD - Google Patents

Abstract

 A zero sequence current filter based on a transformer with a rotating magnetic field consists of three toroidal cores on which four primary windings, a ballast resistor and inductance are located for each of the three phases, the beginning of the first winding being connected to the end of the second winding, forming the first input of the device , the end of the first winding with the end of the third winding, the beginning of the second winding with the beginning of the fourth winding, the beginning of the third winding with ballast inductance, and the end of the fourth winding with ballast a resistor, the other ends of which form the second input of the device when connected, and to obtain a rotating magnetic field in each phase, the first, second, third and fourth primary windings are located relative to each other on a toroidal magnetic core with a 90 ° shift, with the number of turns of the first and the fourth winding is twice as much as the second and third; multiphase secondary windings for each of the three phases are made of two winding systems, each of which contains three windings located relative to each other a friend at an angle of 120 °, and between themselves, these winding systems are geometrically shifted at an angle of 30 ° relative to each other, with the secondary windings of each phase connected in series to each other in a “star”, and its ends connected to the input of a multiphase rectifier, the output of which is rectified signal proportional to the zero sequence current.

Description

The utility model relates to measuring equipment, and more specifically to devices designed to isolate the symmetrical components of an electrical signal, and can be used as part of devices for measuring, protecting and signaling three-phase AC systems.

A known filter of the symmetrical components of the electrical signal (patent No. 2209441, class IPC G01R 29/16) is closest to the claimed utility model for its purpose and the achieved result, in which the phase A clamp of the controlled signal is connected to the first input of the first adder, the phase B clamp connected through the inverting input of the first differentiation unit to the second input of the first adder, and through the inverting input of the first proportional unit to the third input of the first adder, the phase clamp C is connected through a non-inverting input the second differentiation unit with the fourth input of the first adder, and through the inverting input of the second proportional unit, with the fifth input of the first adder, the output of which through the non-inverting input of the third proportional unit is connected to the first output of the device, additionally contains the third and fourth differentiation units, the second and third adders and the fourth and fifth proportional blocks, and the phase A clamp is additionally connected to the first input of the second adder and to the first input of the third adder, the clamp s B is additionally connected to the second input of the second adder, connected to the second input of the third adder through the non-inverting input of the third differentiation unit, and to the third input of the third adder through the inverting input of the first proportional unit, and the output of the second adder through the non-inverting input of the fourth proportional unit is connected to the second the output of the device, the phase C clamp is additionally connected to the third input of the second adder, connected to the fourth input of the third adder via inverting th differentiation of the fourth input of the block, and to a fifth input of the third adder - a second inverting input through a proportional block, the output of the third adder by a fifth inverting input of the proportional block connected to the third output device.

This filter of the symmetrical components of the electric signal, being a close device to the proposed zero-sequence current filter for its intended purpose, allows you to select the full range of symmetrical components of the electric signal, without providing a sufficiently high accuracy of the device, since the filter of the symmetrical components of the electric signal is based on semiconductor elements, therefore, it is a more expensive and less reliable device.

Also known is a single-phase transformer with a rotating magnetic field (OTP) (patent No. 2333562, class IPC H01F 30/14), which is taken as the basis of the zero-sequence current filter, contains four primary windings located on the toroidal core, ballast resistor and inductance, multiphase secondary windings, the beginning of the first winding connected to the end of the second winding, forming the first input of the device, the end of the first winding with the end of the third winding, the end of the second winding with the end of the fourth winding, the end of the third winding - with ballast inductance, and the beginning of the fourth winding with a ballast resistor, the other ends of which form a second input of the device when connected, and to obtain a rotating magnetic field, the first, second, third and fourth windings are located relative to each other on a toroidal magnetic core with a shift of 90 ° the number of turns of the first and fourth windings is two times more than the second and third.

OTP is close to the claimed zero-sequence current filter by the largest number of design features, but cannot be used as a filter of symmetrical components.

The objective of the utility model is to increase the reliability of the power supply system.

This problem is solved in such a way that the zero-sequence current filter based on the OTP contains three toroidal cores, on which four primary windings, a ballast resistor and inductance are located for each of the three phases, and the beginning of the first winding is connected to the end of the second winding, forming the first the input of the device, the end of the first winding with the end of the third winding, the end of the second winding with the end of the fourth winding, the end of the third winding with ballast inductance, and the beginning of the fourth winding with ballast p with a resistor, the other ends of which, when connected, form the second input of the device, and to obtain a rotating magnetic field in each phase, the first, second, third and fourth primary windings are located relative to each other on a toroidal magnetic core with a 90 ° shift, with the number of turns of the first and the fourth winding is twice as much as the second and third, multiphase secondary windings, for each of the three phases made in the form of two winding systems, each of which contains three windings located each other but the other at an angle of 120 °, and between themselves, these systems of windings are geometrically shifted at an angle of 30 ° relative to each other, with the beginning of the winding 15 connected in series with the end of the winding 21, and the beginning of the latter connected to the end of the winding 27, then similarly connected windings of each of the two winding systems are combined in a "star", and its ends are connected to the input of a multiphase rectifier, the output of which forms a rectified signal proportional to the zero sequence current.

The technical result is to increase the accuracy of relay protection and emergency automation in asymmetric emergency modes due to the simplification of the filter design and the use of multiphase secondary windings.

The operation of the device is based on the use of the method of symmetrical components. Let the system of currents of direct sequence be supplied to the input of the filter, which, with the primary windings of each OTP, forms the corresponding magnetomotive forces (MDS) that form the rotating magnetic fields:

where F _m is the amplitude value of the MDS phases A, B, C;

ω is the angular frequency of the signal, ω = 2πf;

f is the signal frequency.

In the secondary windings of each OTP, based on their spatial location, the corresponding voltages are induced having the following phase shifts:

Based on the given connection of the windings, the following voltages are received at the input of the rectifier:

Let the reverse sequence current system be fed to the filter input, which forms the following MDSs, which generate rotating magnetic fields in each OTP:

where F _m is the amplitude value of the MDS phases A, B, C;

ω is the angular frequency of the signal, ω = 2πf;

f is the signal frequency.

In the secondary windings of each OTP, the corresponding voltages are induced:

Based on the given connection of the windings, the following voltages are received at the input of the rectifier:

Let the zero sequence current system be supplied to the filter input, which forms the following MDSs, which generate rotating magnetic fields in each OTP:

In the secondary windings of each OTP, the corresponding voltages are induced:

With this combination of windings, the following voltage signals are input to the rectifier input:

Therefore, the proposed filter at the output forms a system of voltage vectors proportional to the zero sequence currents. Moreover, this system of vectors forms a six-phase rectification system and, due to low ripples, a voltage proportional to the amplitude value of the input current of the zero sequence is released at the output of the rectifier.

Let the two-phase short-circuit currents of phases B and C from the electric network come to the input of the zero-sequence current filter, which form the following MDSs with the corresponding OTP, forming rotating magnetic fields:

The following voltages are induced in the secondary windings:

Then the following voltages arrive at the input of the rectifier:

Thus, in the normal mode of operation of the power supply system, there is no signal at the output of the zero-sequence current filter. In emergency operation, when a short circuit occurs at the output of the device, a signal is generated proportional to the amplitude value of the zero sequence current. The use of six-phase secondary windings allows to increase the accuracy of the filter, due to the reduction of the ripple of the resulting signal. Using instead of semiconductor elements a combination of windings located relative to each other at certain angles, allows to simplify the design of the device, increasing reliability.

The figure 1 presents a schematic electrical diagram of a zero-sequence current filter based on OTP. The primary windings of the filter are located on the toroidal cores 1-3. Clips 4 and 5 are the input terminals of the device of each of the three phases. The current filter for each phase contains two groups of primary counter-connected windings (6, 7 and 8, 9) having a spatial shift of 90 °, as well as a reactor 10 and a ballast resistor 11. Secondary windings 12-14 for each of the three phases are made in in the form of two winding systems, each of which contains three windings located relative to each other at an angle of 120 °, and between these winding systems are geometrically shifted at an angle of 30 ° relative to each other. Moreover, the beginning of the winding 15 is connected in series with the end of the winding 21, and the beginning of the latter is connected with the end of the winding 27. The remaining windings are connected in the same way, each of the two winding systems combined in a “star”, and its ends connected to the input of the multiphase rectifier 33, output which forms a rectified signal proportional to the zero sequence current.

The inventive zero-sequence current filter based on the OTP operates as follows: electric currents with a frequency of 50 Hz and a phase shift of 120 ° relative to each other flow through terminals 4 and 5 of each phase. The primary windings of the phase (6-9) by means of counter-connected sections create a system of two perpendicular and equal in magnitude magnetomotive forces ( and ) in magnetic systems 1-3. The described magnetomotive forces of each phase in turn create a rotating magnetic field, which induces in the secondary windings 12-14, forming for each phase two three-phase systems of windings spatially offset from each other by an angle of 30 °, electromotive forces also have a pair phase shift 30 °, in the end, we obtained a system of voltages with the number of phases equal to 6, which, as a result of connecting to a multiphase rectifier 33, allows a constant signal proportional to the amplitude of the current zero after goodwill.

Using a filter of symmetrical components based on a single-phase transformer with a rotating field allows us to simplify the design of the device, reducing its cost as a result and increasing the reliability of the power supply system. The multiphase of the secondary windings of the zero-sequence current filter allows to increase the accuracy of relay protection and emergency automation, of which the filter is an integral part, to reduce the ripple of the resulting output signal and to allocate a signal proportional to the amplitude value of the zero-sequence current in emergency operation.

Claims (1)

A zero sequence current filter based on a transformer with a rotating magnetic field consists of three toroidal cores on which four primary windings, a ballast resistor and inductance are located for each of the three phases, the beginning of the first winding being connected to the end of the second winding, forming the first input of the device , the end of the first winding with the end of the third winding, the beginning of the second winding with the beginning of the fourth winding, the beginning of the third winding with ballast inductance, and the end of the fourth winding with ballast a resistor, the other ends of which form the second input of the device when connected, and to obtain a rotating magnetic field in each phase, the first, second, third and fourth primary windings are located relative to each other on a toroidal magnetic core with a 90 ° shift, with the number of turns of the first and the fourth winding is twice as much as the second and third; multiphase secondary windings for each of the three phases are made of two winding systems, each of which contains three windings located relative to each other a friend at an angle of 120 °, and between themselves, these winding systems are geometrically shifted at an angle of 30 ° relative to each other, with the secondary windings of each phase connected in series to each other in a “star”, and its ends connected to the input of a multiphase rectifier, the output of which is rectified signal proportional to the zero sequence current.