UA22001U - Device of a reverce brushless excitation of synchronous compensator - Google Patents

Abstract

The device of a reverse brushless excitation of synchronous compensator consists of a rolling optothyristor transformer, an auxiliary generator of alternating current, auxiliary generators mounted on the same shaft where compensator are, an adjustable direct current source, an automatic exciting regulator, a thyristor control system, a thyristor rectifier. Additionally, the device is provided with a thiristor transformer, a null device, and an inhibition unit.

Description

Description of the invention

A useful model refers to electrical engineering and can be used for brushless reversible 2 excitation of synchronous compensators.

Known devices for exciting synchronous compensators, containing a thyristor reversing converter and a sliding current collector on the rotor (11.

The disadvantages of such devices include the low reliability of sliding current collection, especially in the hydrogen environment in large synchronous compensators with hydrogen cooling. 70 Other devices for synchronous compensators are known, containing two excitation windings, in which two independent exciters are connected to each excitation winding to provide a positive and negative excitation current (21. These devices provide contactlessness, but have a large weight, dimensions and low adjustment dynamics.

Known devices for reversible brushless excitation of a synchronous machine, containing rotating thyristor 12 converters and controlled by means of additional control generators |ZI.

These devices provide high regulation dynamics, but have low reliability due to the location on the rotating part of the exciter of non-contact electronic switches of rotary thyristor control pulses and low sensitivity of non-contact current sensors of the valve groups of the rotary reversing converter when implementing a separate control law. The device |Z) is taken as a prototype.

The useful model is based on the task of improving the well-known device of reversible brushless excitation of a synchronous machine by introducing additional elements: a second thyristor converter, two null bodies and two blocking blocks, which provides a simplification of the design and increased reliability of operation.

The problem is solved by the fact that in a known device for reversible brushless excitation of a synchronous compensator, which contains the first and second rotating opto-thyristor converters, which are connected to the armature winding of the auxiliary alternating current generator with the alternating current inputs 29, and with the corresponding direct current outputs through the first and second sensors of the excitation current of the synchronous compensator are connected to the first terminal of the excitation winding of the synchronous compensator, the second terminal of which is connected to the zero terminal of the armature winding of the auxiliary generator, the first and second additional generators, which are installed on the same shaft with the synchronous compensator, the armature windings of which are connected to the control electrodes of the first and the second rotating - optothyristor converters, respectively, and the excitation windings are connected to an adjustable direct current source Ha"), an automatic excitation regulator, the input of which is connected to the outputs of the voltage and current sensors of the stator winding of the synchronous compensator, and the output m through the thyristor control system is connected to the control input of the thyristor rectifier, the direct current output connected to the excitation winding of the auxiliary generator, the new thing is that a second thyristor converter is additionally introduced, the output is connected opposite-parallel to the output of the first thyristor converter and the control input c connected to the output of the automatic excitation regulator through the second thyristor control system, the first and second zero bodies, the inputs of which are connected to the outputs of the first and second sensors of the excitation current of the synchronous compensator, and the outputs are respectively connected to the inputs of the second and first introduced blocks " prohibitions, first and second controlled keys, which are included in the connection points of the regulated source of direct current C 740 with the excitation windings of the first and second additional generators, respectively, and the control inputs of the first and c of the second controlled keys are connected to the outputs of the first and second blocks of prohibition, respectively.

From" Fig. 1 shows the schematic diagram of the device.

Fig. 2 shows the schematic diagram of the block of prohibition and the controlled key.

To simplify the power supply, the schematics for all static elements are not shown. They can be solved in any known ways, for example, with the help of transformers connected to the power output of the synchronous compensator. ka The device of reversible brushless excitation of the synchronous compensator 1 contains the first 2 and the second Z rotating opto-thyristor converters, which are connected to the armature winding 4 o of the auxiliary alternating current generator 5 with alternating current inputs. The combined output of the same polarity of the first 2 and the second Z o 20 rotating opto-thyristor converters through the first 6 and second 7 sensors of the excitation current of the synchronous compensator, respectively, are connected to the first terminal of the excitation winding 8 of the synchronous compensator 1. and the second terminal of the excitation winding 8 is connected to the zero terminal of the armature winding 4 of the auxiliary generator 5 connected in a star. In the scheme, there are the first 9 and the second 10 additional generators, which are installed on one shaft with a synchronous compensator, the armature windings 11, 12 of which are connected to the control electrodes of the first 2 and the second 29 rotating opto-thyristor converters, respectively. The excitation winding 13 of the first 9 and the excitation winding c 14 of the second 10 additional generators are connected to an adjustable direct current source 15. The automatic excitation regulator 16 is connected to the outputs of the voltage 17 and current sensors 18 of the stator winding 19 of the synchronous compensator 1. The output of the automatic excitation regulator 16 connected to the control input of the thyristor converter 20 through the thyristor control system 21. The output of the thyristor converter 60 20 is connected to the terminals of the excitation winding 22 of the auxiliary generator 5. The second thyristor converter 23 is connected in parallel to the first thyristor converter 20. The control input of the second thyristor converter 23 connected to the output of the automatic excitation regulator 16 through the second thyristor control system 24. The scheme has the first 25 and the second 26 null bodies, the inputs of which are connected to the outputs of the first b and second 7 sensors of the excitation current of the synchronous compensator 1, and the outputs, respectively, are connected to entrances of the second 27 and first 28 blocks of the ban. The circuit includes the first 29 and second 30 controlled keys, which are included in the connection points of the adjustable direct current source 15 with the excitation windings 13, 14 of the first 9 and second 10 additional generators.

Excitation current sensors 6, 7 of the synchronous compensator 1 provide electromagnetic signal transmission when the current flows through the excitation winding 8. Additional generators 9, 10 are made for the number of pole pairs, which is equal to the number of pole pairs of the auxiliary generator 5. EMF of the armature windings 11, 12 of the additional generators 9 , 10 can have a sinusoidal or sawtooth shape. In the latter case, we have teeth on the armature of the additional generator, the number of which is equal to or a multiple of the number of phases of the auxiliary generator of alternating current 5, and each tooth has a head developed in the tangential direction and a technologically or mechanically minimally thin leg, on which the phase of the armature winding of the additional generator is dressed . Due to the use of the saturation effect of the thin leg of the armature tooth, the EMF in the armature phase has a sawtooth pulse shape in time with a sinusoidal shape of the magnetomotive force of the excitation windings 13, 14 in space, that is, the magnetic formation of the control pulse is realized in the additional generator itself.

When using additional generators 9, 10 with a sinusoidal form of EMF in phase, the magnetic formation of /5 pulses can be performed using saturation chokes.

The stators of additional generators U, 10 have the possibility of mechanical rotation in order to align the electric axes of their poles with the electric axes of the poles of the auxiliary generator 5 and to set the control angle of the optothyristors 2, Z sumo.

Additional formation of voltage pulses of the armature windings 11, 12 can be achieved using pulse formation systems (not shown in Fig. 1). Each pulse generation system is a series-connected diode that cuts off the non-working half-wave of the EMF, a zener diode that cuts off the positive part of the working half-wave and performs interference protection, and a resistor that limits the current value of the control electrode of the optothyristor.

The auxiliary generator of alternating current 5 is made three-phase in clear-polarity or implicit-polarity

Made with a sinusoidal form of EMF in phase.

Analog comparators |4| can be used as the first 25 and second 26 zero-organs at c) reference voltage Ospa0. In this case, the comparators are switched at the input voltage Овх»О and are a zero-level detector.

The prohibition block 27, (28) is a set of two logical elements "AND" 31, 32 and a logical element - "NO" (Fig. 2).

The operating principle of the controlled key 29 (30) is a trigger based on a two-operation thyristor 34, which is controlled using multipolar pulses, which are generated by two separate pulse generators of opposite polarity 35, 36, which are connected to the control electrode of the thyristor 34 through optothyristors 37, 38.

Optothyristor converters 2, C can be made according to any known rectification scheme. with

The power sources of the first 20 and second 23 thyristor converters, the automatic regulator and excitation 16 and other static elements of the device are not shown in Fig. 1. They can be solved by any known means (using transformers connected to the stator winding 19 of the synchronous compensator, sub-exciter, etc.). "

Oppositely connected thyristor converters 20, 23, which form a two-group reversing converter, have the same power supply and are controlled, for example, according to the coordinated control scheme. - c The device works in the following way. Suppose that during the operation of the synchronous compensator 1 in the reactive power output mode, the first opto-thyristor converter 2 is in the conductive state. At the same time, the control angle "" of the opto-thyristors is equal.

At the same time, let's also assume that the first thyristor converter 20 is in operation, which ensures the flow of current through the excitation winding 22 of the auxiliary generator 5. Let's assume that the excitation current of the synchronous compensator Id exceeds the specified lower level Is»Ivstip. At the same time, there will be a logical "1" signal at the output of the first zero-organ 25, and a logical "0" signal at the output of the second zero-organ 26 (the current does not flow through the second excitation current sensor 7). The logical signal "1" from the output of the first zero-organ (av) 25 enters the input of the second block of prohibition 27, which causes the second controlled key 30 to be turned off. At 50, the excitation of the second additional generator 10 is removed, which ultimately leads to the removal of pulses control from the control electrodes of the second opto-thyristor converter 3. In operation - there is the first additional generator 9, which ensures the formation of control pulses for the rotating opto-thyristors 2.

Regulation of the excitation current of the synchronous compensator 1 is carried out using the automatic excitation regulator 16 by influencing the latter on the control input of the first thyristor converter 20 through the first thyristor control system 21 depending on the signals from the voltage sensors 17 and current 18 of the stator winding 19 of the synchronous compensator 1. At the same time there is a change in the excitation current and, accordingly, the voltage of the armature winding 4 of the auxiliary generator 5, which is rectified by the first opto-thyristor converter 2 and applied to the excitation winding 8 of the synchronous compensator 1. At the same time, the control angle of the opto-thyristors 2 is constant and approximately equal to zero. Suppose that the synchronous compensator 1 in the reactive power consumption mode requires a change in the direction of the excitation current of the synchronous compensator 1 to the opposite. The corresponding output signal of the automatic excitation regulator 16 switches the first thyristor converter 20 into inverter mode, which causes its output current to drop to zero and simultaneously activates the second thyristor converter 23. The activation of the latter 65 leads to a change in the direction of the excitation current of the auxiliary generator 5.

In the process of reversing the excitation current of the auxiliary generator 5, the excitation current of the synchronous compensator 1 (assuming a positive direction) from the first opto-thyristor converter 2 drops to zero. When the current reaches | at the value of the I input, the logic "1" signal at the output of the first zero-organ 25 will change to a logic "0" signal, while the logic signal "Enable" will appear at the output of the second block of prohibition 27. The second controlled key 30 will go into the on state and will provide excitation of the second additional generator 10, i.e. putting it into operation. Thus, when IvhIv tip Both additional generators 9, 10 are in operation, the control pulses simultaneously arrive at the control electrodes of the first 2 and the second Z rotary opto-thyristor converters. The principle of joint control of the optothyristors of the first 2 and second Z converters is implemented. After the complete extinguishing of the magnetic flux of the positive excitation 7/0 of the auxiliary generator 5 under the influence of the negative current in the excitation winding 22 EMF in the armature winding 4 of the auxiliary generator 5 changes its phase by 180 electrical degrees. The second opto-thyristor converter C will start working. The current in the excitation winding 8 will change its direction. If the negative excitation current of the synchronous compensator becomes less than the minimum level | In e-Ietia, a logical signal "1" will appear at the output of the second zero-organ 26, which acts on the first controlled key 29 through the first block of prohibition 28 and will disconnect the excitation winding 13 of the first additional generator 9 from the source of direct current 15. The first additional generator 9 will be taken out of operation. Only the second additional generator 10 remains in operation, which ensures the operation of the second opto-thyristor converter 3.

The limitation of the power of the negative excitation of the synchronous compensator 1 (102095 nominal power with positive excitation) can be provided by limiting the negative excitation current in the winding 22 of the auxiliary generator by setting the corresponding fixed control angle of the second thyristor converter 23.

Thus, the device makes it unnecessary to install on the rotating part complex electronic devices for controlling the rotating reversing converter, highly sensitive non-contact current sensors of thyristor or opto-thyristor converters, allows to increase the reliability of the device and simplify the design of the rotor of the synchronous compensator and the actual brushless reversing exciter.

The proposed device can be implemented on the existing element base of the converting equipment. in)

Sources of information: 1. Author's certificate of the USSR Mo440757, class NO2 R 9/10, 1974. 2. Vorobey V.K., Pekne V.3., Fedorov V.F. Brushless exciter of the compensator 50 MVA - Zlektrotekhnicheskaya promyishlennost, Ser. Electrical machines, vyp. 10(44) 1974

Z. Author's certificate of the USSR BI Mo1361704A1, kl NOg2r 9/14, 9/30, 1987. o 4. Brammer Yu.A., Pashchuk I.N. Impulse technique: Textbook. for students of electrical engineering schools and technical schools. - 5th ed. processing and additional - M.: Higher School, 1985, 320 p., illus. with

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Claims (1)

The formula of the invention is a device for reversible brushless excitation of a synchronous compensator, containing the first and second rotating opto-thyristor converters, which are connected to the armature winding of an auxiliary "alternating current generator" by means of alternating current inputs, and connected to the corresponding direct current outputs through the first and second current sensors U with the excitation of the synchronous compensator to the first terminal of the excitation winding of the synchronous compensator, the second terminal of which is connected to the zero terminal of the armature winding of the auxiliary generator, the first :z" and the second additional generators, which are installed on the same shaft with the synchronous compensator, the armature windings of which are connected to the control electrodes of the first and the second rotating opto-thyristor converters. Accordingly, and the excitation windings are connected to an adjustable direct current source, an automatic GI excitation regulator, the input of which is connected to the outputs of the voltage and current sensors of the stator winding of the synchronous compensator, and the output through the ke system thyristors are connected to the control input of the thyristor rectifier, the direct current output connected to the excitation winding of the auxiliary generator, which differs in that a second thyristor converter is additionally introduced into it, the output is connected in parallel with the output of the first thyristor converter and the control input is connected to the output of the automatic excitation regulator through the second thyristor control system, the first and second zero bodies, the inputs of which are connected to the outputs of the first and second sensors of the excitation current of the synchronous compensator, and the outputs are respectively connected to the inputs of the second and first introduced blocks of prohibition, the first and second controlled keys that are included in the connection points of the adjustable direct current source with the excitation windings of the first and second additional generators, respectively, and the control inputs of the first and second controlled keys are connected to the outputs of the first and second blocks of the prohibition, respectively. 60 b5