SU1561187A1 - Power plant - Google Patents

Abstract

The invention relates to electrical engineering and is intended to improve the excitation systems of power plants with high-power electrical machines used primarily in nuclear power plants. The aim of the invention is to increase reliability. The device contains the main synchronous machine 1 and the first auxiliary generator 4 installed on its shaft, the winding of the core of which, through the first rotating controlled rectifier 2, is connected to the excitation winding 7 of the synchronous machine. The device also contains a second auxiliary generator 26, the fixed root winding 28 of which is connected via the second (fixed) controlled rectifier 20 and the brush-contact unit also to the excitation winding of the main synchronous machine. The joint operation of the two control systems provides for the current regulation of the excitation of the main synchronous machine by a contactless method using the first auxiliary generator 4, and forcing the excitation through the brush-contact unit with the help of the second auxiliary generator 26 and the controlled rectifier 20. In addition, this device construction in normal operation mode, to ensure optimal operation of the brush-contact unit and reduce the current through the slip rings from the first auxiliary generator 4. pa 5 yl.

Description

The operation of the two control systems provides for the current regulation of the excitation of the main synchronous machine by the contactless method using the first auxiliary generator 4, and forcing the excitation through the brush-contact unit with the help of the second auxiliary generator 26 and the controlled rectifier 20. In addition, this device construction in normal operation mode, ensure optimum operation of the brush-contact unit and reduce the current through the slip rings from the first auxiliary generator 4 5 il.

The invention relates to electrical equipment, namely to power installations comprising synchronous high power machines, for example turbo generators, and a device for controlling them.

The aim of the invention is to increase reliability.

Figure 1 shows a schematic diagram of the excitation of a power plant and nodes for a synchronous machine; 2 shows the load characteristic of the device; FIG. 3 shows rectified voltage diagrams on the excitation winding of a synchronous machine; 4 is a schematic diagram of a potential signal distributor gg la; figure 5 - the ideal characteristics of a potential signal distributor.

The power plant contains the main synchronous machine 1 (Fig. 1) 9, the first controlled rectifier 2 located on the rotating part of the unit and the AC terminals connected to the first main winding 3, the first auxiliary synchronous generator 4, the excitation winding 5 which is connected to the output of the amplifier 6. The DC terminals of the first controlled rectifier 2 are connected to the excitation winding of the main synchronous machine 1. In the circuit there are first 8 and second 9 contact rings connected respectively the positive and negative poles of the first controlled rectifier 2. The diagram (Fig.) shows an additional synchronous generator 10, the root winding 11 of which is connected through the pulse shaping unit 12 to the control input of the first controlled rectifier 28 and its first 13 and second 14 mutually perpendicular windings of the inductor are connected to the output of the sine-cosine functional converter 15. There is an automatic excitation controller 16, the first and second information inputs of which are connected to the date outputs Ikov 17 voltage and 18 current anchor main winding 19 of the synchronous machine I. The second controllable rectifier 20, the positive and negative poles respectively connected to first 8 and second 9 alternation first slip rings 21 and the second brush units 22. The control input of the second controlled rectifier 20 is connected to the output of the second control unit 23.

An uncontrolled rectifier 24, located on the rotating part of the unit, is additionally introduced into the device, the AC leads of which are connected to the additionally introduced second main winding 25 of the first auxiliary generator 4, the second auxiliary synchronous generator 26 is also introduced into the device, the excitation winding 27 is connected with the output of the uncontrolled rectifier 24, and the root winding 28 - with the outputs of the alternating current of the second controlled rectifier 20.

A three-threshold signal distribution unit 29 is introduced into the device, the input of which is connected to the control output of the automatic excitation controller 16. The first, second and third outputs of the unit 29 are connected respectively to the input of the sine-cosine function converter 15, to the input of the control unit 23 and the input of the amplifier 6.

The device works as follows.

Assume that synchronous machine 1 operates as a synchronous turbogenerator.

Assume also that the voltage at the output of the first root winding 3 of the first auxiliary synchronous generator 4 is lower than that at the output of the root winding 28 of the second auxiliary synchronous generator 26.

Let us call the first controlled rectifier 2 working, and the second controlled rectifier 20 forced.

The operation of the device in this mode is as follows.

Depending on the signals from the voltage sensors 17 and 18 and the current of the synchronous machine 1, the automatic excitation controller 16 outputs a control signal Uy, which from the first output of the block 29 enters the input of the sinus-cosine function converter 15, which converts the input signal so that the currents at the output of the converter 15 in the first 13 and second 14 windings of the inductor of the additional generator 10 are changed according to the law

 losinkU ,; If4 IecoskUy; where I0 is the current on the windings of the inductor; k is the gain.

Thus, the first 13 and second 14 windings, shifted one relative to the other by 90 el. Degrees, create a magnetic field in the gap of the additional generator 10 with an amplitude proportional to the sum of the squares of sine and cosine of the same magnitude, i.e. constant, regardless of the magnitude of the control signal. The angle in the resultant vector of the magnetic field, defined by the sine and cosine of the signal from the first output of block 29, is proportional to this signal. Accordingly, the temporal angle of the electromotive forces (EMF) induced in the core windings 11 of the additional generator 10 also turns out to be ProP)

portioned to the signal from the first output of block 29 (to the signal from the output of the automatic excitation controller 16). When the emf in the root winding 3 of the first auxiliary synchronous generator 4 emf is constant in time, the root winding 11 of the additional synchronous generator 10 through the pulse shaping unit 12 acts on the control circuits of the first

about

Jq

jj 20, "

.,.

50

55

controlled rectifier 2 with an appropriate adjustment angle, which determines the appropriate amount of current in the excitation winding of the synchronous machine 1.

In addition to the process described, the signal from the second output of the unit 29 through the amplifier 6 changes the current in the excitation winding 5.

In accordance with the magnitude of the current in the excitation winding 5 of the first synchronous auxiliary generator 4, an emf is induced in its second root winding 25, which is rectified by an unmanaged rectifier 24 and causes a flow of direct current in the excitation winding 27 of the second auxiliary synchronous generator 26.

The induced emf in the winding 28 of the core of the second auxiliary synchronous generator 26 is outputted using the second controlled rectifier 20. The control angle of the second controlled rectifier 20 is changed in accordance with the signal from the second output of the block 29 using the second control unit 23.

Thus, the current in the excitation winding 7 of the synchronous machine 1 from the second controlled rectifier 20 is determined not only by the magnitude of the EMF in the winding 28 of the second auxiliary synchronous generator 26, but also by the angle of regulation of the second controlled rectifier.

In the excitation winding 7 of the synchronous machine 1, a sum of currents flows, determined by the output current of the first controlled rectifier 2 and the second controlled rectifier 20.

With the help of block 29 (selection of its elements 30-43), the characteristics to which the device is tuned in this mode of operation are shown in Fig. 2, where 1a is the current in the excitation winding 7 of the synchronous machine 1 from the first controlled rectifier 2 ; the current in the excitation winding 7 of the synchronous machine 1 from the second controlled rectifier 20; I is the current in the excitation winding 7 from the first 2 and second 20 controlled rectifiers; i is the current in the excitation winding 5 of the first auxiliary synchronous generator 4. Curve 1g corresponds to the diode mode of operation of the first controlled

straightener 2 when fully open. The curve Iie also corresponds to the diode mode of the second controlled rectifier 20, when it is fully open throughout the entire control range. Curves -1 and Ij0 correspond to the mode of operation. As can be seen from Fig. 2, with I 1 "1 g + 1 2 o the rated excitation current of a synchronous machine, the nominal excitation current of generator 4 is 1H.

When forcing a signal from the automatic excitation controller 16, the first controlled rectifier along the 16-29-15- (13,14) -11-12 2 circuit opens completely, the second

controlled rectifier 20 on a chain 16-29-23-20. At the same time, the excitation of the first auxiliary synchronous generator 4 along the chain 16-29-6-5 and the second auxiliary synchronous generator 26 along the chain 16-29-6-5-25-24-27 occurs.

To the point of intersection of the curve l and I / j, the process of changing the current from the first controlled rectifier 2 occurs along the curve (Fig. 2, point a), and then along the curve 1g (point b).

The current from the second controlled rectifier 20 varies along curve ll to point c.

At point c, an increase in the current of the output of the second controlled rectifier I / occurs and the simultaneous decrease to zero of the current from the first controlled

straightener i. Physically, this is due to the fact that the valve group entering into operation (rectifier 20) locks the valve working group (rectifier 2), since has a higher supply voltage.

The current in the winding 7 of the excitation from point d to point e (curve) varies with s along curve I.

From Fig. 2 it follows that the curve can be almost linear over the entire range of variation of the excitation current of the auxiliary generator 4.

Point e along curve 120 corresponds to the forcing value of currents 1ph and i with 1ph 1.1-1.2 iH, i.e. generally accepted in brushless drivers of powerful synchronous generators.

If in accordance with the new situation in the power system, the automatic regulator J6 changes

five

0

five

0

five

the output signal to the opposite (negative), then block 29 switches the amplifier 6 to the mode providing the current i0 in the excitation winding 5, the first controlled rectifier 2 to the operation mode with the maximum control angle equal to the control angle of the second controlled rectifier, those. about (g t / 2e mox

Due to this, a negative voltage appears on the excitation winding 7 of the synchronous machine 1, the absolute value determined by the voltage on the first main winding 3 of the second auxiliary generator 4 and in accordance with the current 10 in the excitation winding 5. The process of the excitation of the synchronous machine 1.

The quenching of the field of the synchronous machine 1 is accomplished by turning off the first controlled rectifier 2 and transferring the second controlled rectifier 20 to the inverter mode. This ensures the appearance of a higher negative voltage on the excitation winding 7 and, therefore, more intensive field quenching (the quench circuit in FIG. 1 is not shown).

It should be noted that the current in the excitation winding 5 of the auxiliary generator 4 during the field quenching process can be set to 10 or i $ (Fig. 2).

0

five

Fig. 3 shows the curves of straightened voltages on the winding 7 of the excitation of the synchronous machine 1 in various modes of its operation. In addition, in FIG. 3, the voltage curves of the core windings 3 and 28 (Uj and U) do not reflect the effect of the excitation current in the winding 5 of the first auxiliary generator 4, i.e. the amplitude of the illustrated stresses U3 and Ujg is constant.

It should be noted that with appropriate calculation and coordination of the characteristics of the first 4 and second 26 auxiliary generators, when the current in the winding 5 changes, the ratio of the voltages U and U. will be maintained unchanged.

Thus, the invention makes it possible to increase reliability and provide good energy performance. This is achieved by the fact that it simultaneously implements

y15

contact and brushless excitation systems for synchronous machines.

The current in the excitation winding of the synchronous machine is provided by both rotating and static parts of the device. At the same time, the current regulation of the excitation current of the synchronous machine is provided mainly by the brushless part of the device, and the static part provides the excitation current component determined from the level of optimal operation of the slip rings in the continuous mode (it is known that the mechanical wear of the brushes without load current occurs faster than under current). The drive current of the synchronous machine is mainly carried out by the static part of the device.

This circumstance allows to reduce the dimensions of the rotating part of the device, since There is no need to rely on the force mode.

The working conditions of the brush-contact unit are improved} in the long-term mode, it is loaded with a current that is much lower than the nominal, which increases the reliability of the brush-contact unit and the entire turbogenerator.

The working conditions of the brush-contact unit intended for reserving the device of non-zero excitation are improved, since the current load of the brush-contact unit can be chosen optimally in the long-term mode from the point of view of ensuring mechanical and thermal stability.

Claims (1)

Invention Formula The power plant, containing the main synchronous machine, the first controlled rectifier, the ranging current of the second controlled The alternating current is connected to the first main winding of the first auxiliary synchronous generator, the excitation winding of which is connected to the amplifier output, the DC outputs of the first controlled rectifier are connected to the excitation winding of the main synchronous ma the rectifier, a three-threshold signal distribution unit with three outputs, the input of which is connected to the output of the automatic excitation controller, and the first, second and third outputs are connected respectively to the inputs of the function converter, the second thyristor control unit and the -amplifier. ten 0 five 0 tires, the first and second contact rings of the brush-contact node of the main synchronous machine, connected respectively to the positive and negative terminals of the first controlled rectifier, an additional synchronous generator, the root winding of which through the pulse shaping unit is connected to the control input of the first controlled rectifier, and the first and second mutually perpendicular windings of the inductor are connected to the output of a sine-cosine functional converter, an automatic excitation regulator audio, the first and second data inputs of which are coupled to the outputs of the sensors voltage and current anchor main winding of the synchronous machine, characterized in that, in order to increase the reliability, in the first auxiliary sinhron5 Q five 0 An additional root winding is placed on the generator, a second controlled rectifier with a control unit is additionally inserted, the positive and negative poles of which are connected respectively to the first and second contact rings via the first and second brushes, and the control input is connected to the output of the control unit of the second control rectifier, uncontrolled rectifier located on the rotating part of the unit, the AC outputs of which are connected to the additional primary winding of the first auxiliary generator, a second auxiliary synchronous generator, whose excitation coil associated with the release of an uncontrolled rectifier and the roots of the winding is connected to pin pe0 the rectifier, a three-threshold signal distribution unit with three outputs, the input of which is connected to the output of the automatic excitation controller, and the first, second and third outputs are connected respectively to the inputs of the function converter, the second thyristor control unit and the amplifier. LIO 0i L titO. 4e “Irt.j; 2 Hf5 Omt o-j . " ls UKW 20 061 (23) ffsfy M - UJx (6) Uto (i5) 2.20.6 r // x /) min 6 idyh (1 $ # 2- 20- & s control angles perdogo 2, the second 20 beats / unit / day / x byprite / gay and amplifier 6. Faye. five