SU1127981A1 - Method for controlling steam turbine - Google Patents

Abstract

A METHOD FOR REGULATING A STEAM TURBINE with a generator operating in the power system, by shaping the control actions on the turbine servomotor according to given values of the power servo position and degree of static, taking into account feedbacks on the actual position of the servo motor and power, measuring the rate of change of the MOBQIOCTH turbine, and the turbine per turbine of the turbine tube and the turbine tube of the turbine tube and the temperature of the turbine tube and the turbine tube and the turbine tube used in the turbine generator. speeds with a threshold value, JO tl h ay i and so, in order to increase the reliability of the turbine and increase the production of electric power, after higher than the speed of change The values of the threshold value 9nacre1 {the formation of waval {common effects are carried out according to the proportion of the o-integral. the law disables power feedback, reduces the degree of statism and after all (the cert is amp & 4 days and with no interval in the specified interval and is medium and the power value of the threshold value sets the volatility of the servomotor according to its own turbine noise.

Description

UD 00

The invention relates to heat. power engineering and can be used to automate the regulation of steam turbines with a generator operating in the power system. .

The closest to the invention in technical essence and the achieved result is a method of regulating a steam turbine with a generator operating in the power system by generating control actions on the servo-motor of a turbine according to specified values of the servo-motor position and power of the turbines and comparing this speed with the threshold m value

The disadvantages of this method are the somewhat reduced reliability of the plant and the lack of opportunities to generate electricity.

The purpose of the invention is to increase the reliability of the turbine and increase power generation.

In order to achieve this goal in the method of regulating a steam turbine with a generator, I work. in the power system by shaping the control effects on the turbine sevomotor according to the servo motor position, power and degree of statism feedbacks on the actual servo position and power, measuring the speed of the turbine power change and comparing this speed with the threshold value after the change speed power thresholds the formation of control actions are proportional-integral law, rtklyuchayut feedback power, reduce the degree of stat Ism and after a time lag and in the absence of exceeding the average power for a given time interval, the threshold values set the position of the servomotor corresponding to their own.

turbine needs.

The drawing shows an example of a block diagram of an apparatus for carrying out the proposed method.

The device contains a regulator 1 connected to the servo-motor 2 of the turbine 3, the sensor 4 of the actual position of the servo-motor 2 and the sensor 5 of the actual power of the turbine 3, the differentiator 6, the threshold element 7, the switching signal generating unit 8, the switches 12-13, compare unit of power 14, unit 15 of the current position of the servomotor, unit 16 of the degree of statism, unit 17 of the position of the servomotor corresponding to the turbine’s own needs, unit 18 of a reduced degree of stat fa, and time delay element 19.

The input of the differentiator 6 is connected to the power sensor 5, and the output to the input of the threshold element 7 connected to the inputs of the switches 10 and 11 of the regulator 1 and through the delay element 19 to the input of the block 8. The input of the comparison element 13 is connected to the power sensor 5, and , to the setpoint of the 14 mop, and the output to the input of the switch 10. The input of the switch 11 is also connected to the setter of the 16th degree of statism and the setter 18 of a reduced degree of statism, and the output to the input of the regulator 1. The input of the unit 8 is also connected to the sensor 5 power, and the output - to the input of the switch 9, connect ennogo also to setting elements 15 and 17 and the corresponding te.kzptsego own needs turbine servo positions respectively. The input of the comparison element 12 is connected to the servo-motor position sensor 4 and the output of the switch 9, and the output to the input of the switch 10, the output of which is connected to the input of the regulator 1.

The regulator 1 may contain the first block 20 forming the alignment cf (their effects, the second block 21 forming the control actions according to the integral control law and the switch 22, one input of which is connected to the output of block 20, the other to the output of block 21, and the third to the threshold element 7.

The switching signal generation unit 8 may comprise a mean power generator 23, a timer (time counter) 24, threshold elements 25 and 26, a threshold power setting unit 27, a mean power value setting unit 28, and conjunct element 29. one

of The input of the block 8 is connected to the input of the timer 24 and the input of the generator 23, the other input of which is also the input of the block 8. The output of the block 8 is the output of the conjunction element 29, one input of which through the threshold element 25 is connected to the output of the generator 23, and the other input through the threshold element 26 - with the output of the timer 24. With the threshold element 25 is connected setpoint 27, and to the threshold element 26 - setpoint 28.

The method is carried out as follows.

Steam turbine 3 is adjusted at load shedding without indication of generator disconnection and oscillations

in the power system by shaping in regulator 1 control actions on the servo motor 2 of the turbine 3, taking into account feedbacks on the position of the servomotor and power, given the position of the servo motor, power and frequency-power statistics. With this, c. the differentiator 6 measures the rate of change of the turbine power, which in threshold element 7 is compared with a threshold value. If the speed does not exceed the threshold value, from the output of the threshold element 7 to the first inputs of block 8,

switches 10 and 1.1 and adjustable. Control 1 does not receive control signals and control actions in controller 1 are generated as follows. ;

The input of the block 20 through the switch 10 is fed from the code of the comparison element 13 by the current power deviation (the signal from which is supplied from the power sensor 5 to the input of the comparison element 13) from the set value (the signal from which sets the power 14 and also to the input of the 13 element compare). To the input of the unit 20 black. Re switching taler 11 comes from the setting device 16 as the signal for a given. degrees of statism. The unit 20, via a switch 22, controls the inputs to the input of the servo motor 2 according to the law, which corresponds to the previous load shedding and to the power system swing to the turbine control mode. .

279814

This law, in general, can be any. It is important that after the moment of determining the load shedding or oscillations, in the power system, the regulation law 5 is proportional-integral m. Therefore, after exceeding the rate of change of the power of the threshold value from the output of threshold element 7 to 10, the inputs of switches 10 and 11, controller 1, and through element 19 of delay to the first input of unit 8 receive control signals. In this case, the switch 22 turns off the signal f5 of the unit 20 and connects to the input of the servomotor. 2 signal of block 21, which forms control actions according to proportional-integral law. Switch 10 disconnects the signal from the elevation of the comparison element 1 and connects to the input of per taculum 1 a signal on the deviation of the current position of the servo motor (the signal from which comes from a 25Ka 4 sensor to the first input of the comparison element 12) from the given one 9 to the second input of the comparison element 12), the switch 11 30 turns off the signal of the setting device 16 and connects to the input of the controller 1 a signal from the setting device 18 of the same degree of statism ;. After a delay in element 19 for the time qHiDseHKH

-, power up to own level

needs for load shedding comes

control signal to timer 24 and driver input 23. Timer 24 starts counting the time, the signal for Q which arrives at the threshold

element 26, where it is compared with the signal over a predetermined time interval for measuring the average power value from the setting unit 28. With 5 scientific research institutes of a given time interval from the output of the threshold element 26 to the input of the conjunction element 29, the control signal is received. The control signal on the driver (eg 23) starts forming a threshold element 25 from the output of the driver (23) according to the average power value, the signal on the current value of which comes from the sensor

5 power input shaper 23.

When a signal is generated by the generator-, the ripper 23, the threshold value from the setting device 27, the threshold element 25

forms at the input of the element 29 of the ion control signal. When a control signal conjuncture element 29 appears at the same time, it generates a control signal to switch 9, which leads to the disconnection of the signal from the auxiliary terminal 15 of the current half-core. the servomotor and the connection to the second input of the element 12 in comparison with the generator from the sensor 17 of the servomotor, which corresponds to the needs of the turbine. In the opposite case, the control signal to the switch 9 is not received, the input of the ele- ment (comparison 12) receives the signal of the setting 15. The driver 23 of the average Power may be shown, for example, as an integrator with gain ratio, where T is the integration duration, peaJ function

t.

p1

about. where N is the integrator input.

In the discrete case of a truncher. 23 with n. adder and clock counter must implement the function

I "

L.T m V

where n is the number of measurement cycles;

N is discrete power values.

Thus, if the average power of the threshold value is not set for a predetermined time interval, the predetermined position of the servomotor is set to correspond to the turbine's own needs.

The threshold value for the rate of change in power can be determined experimentally by measuring the minimum in 1 speed of change in mogress when testing load shedding in a particular control system.

The magnitude of the delay in the beginning of the formation of the average power value is determined for dc1 | achieving power from the turbine to the level of own values of n i am at load shedding-.

To distinguish between load shedding and swinging in the power system, the fact that the power is equal to the magnitude

turbine auxiliary power after a certain time ate a load shedding. The need to measure the average power during a given time interval is caused by the need to: Eliminate the false definition of load shedding in a situation where, when power system is swung, there is a moment for measuring the deviation of mobility from the level of auxiliary needs to approximately coincide with the passage of the fluctuating power. power levels of their own needs.

On this basis, the threshold value of the average power (deviation from the 1st value) is defined as the maximum error of the average power meter, which is usually about 1-2% of the nominal power summed with the power of the turbine's own needs.

The value of the specified time interval is selected from the following conditions. On the one hand, it should be sufficient, but large, so that, when the oscillations are running, the average power has time to change by an amount exceeding the insensitivity zone of the meter. On the other hand, it must be small enough to respond to the load in a timely manner; load shedding, namely, to set the set position of the servomotor to meet the turbine's own needs.

Load shedding and synchronous oscillations in the power system are characterized by significant fluctuations in the sensor readings in amplitude and speed from 1 Neni, distorting the actual nature of the change in turbine power. Under these conditions, switching from static-frequency-frequency to static-frequency regulation of the servomotor eliminates false readings of the power sensor and, in terms of amplitude, decreases the average power of the turbine at synchronous speeds. The decrease in the degree of static characteristics of the frequency-position of the servomotor leads to an increase

the speed of the regulator, which is necessary at a load shedding, which is a more critical mode than the swing mode in the power system. The specific magnitude of the reduction in the degree of statism depends on the specific characteristics of the real turbine, and should: be large enough to limit the fluctuations in power of the frequency swings in the power system, if possible.

More determination of the moment of transition to the load shedding mode or the swing mode of the energy system by analyzing the rate of change of power allows timely and automatically switch to pi control with feedback

on servo position sensor and reduced degree of statism. Definition of the fact; availability of precisely load shedding with the help of additional ibHoro analysis of average power. the turbine allows timely setting of the set position of the servomotor to the turbine's own corresponding needs, which leads to an increase in the degree of readiness of the turbine for restarting.

The use of a proportional control law in the law allows for quick

the response to the load shedding, and the use of the integral component to smooth the oscillations of the controlled parameter during oscillations in the power system. In this case, it is chosen from the condition of minimizing the casting of the rotor rotation speed when resetting

5, and then, from the condition of ensuring a minimum decrease in the average power at synchronous pumping, fish is fired at a fixed value proportional to the principle of the constant-time integral component.

“Thus, the proposed method improves the quality of regulating the steam turbines during load shedding without a sign of the generator disconnection and power swing. me by providing automatic response to oscillations in the power system

0 and more accurately determine the discharge / load, the higher the degree of readiness of the turbine to be restarted after the load is dropped and the change in the average value is limited.

5 power with synchronous oscillations. Correspondingly, the turbine reliability is increased by reducing the operating time. At an increased rotor speed, it decreases

0 the loss of energy consumption and its quality is increased due to the acceleration of the preparation of a tourbine, to restart and limiting changes in the average power value.

Yegen

Claims (1)

METHOD FOR REGULATING A STEAM TURBINE with a generator operating in the power system by generating control actions on the turbine servomotor based on the given values of the servomotor position, power and degree of statism, taking into account feedbacks on the actual position of the servomotor and power, changing the speed of change of the turbine power and comparing this speed with a threshold value, with the exception of that, in order to increase the reliability of the turbine and increase the generation of electric energy, after exceeding the rate of change of power and threshold value generation control actions carried out as proportional-integralnomuzakonu, disconnect the feedback power is reduced and the degree of droop after vderzhki time and at a. the absence of a threshold for a specified time interval, the power value of the threshold value sets the position of the servomotor corresponding to the turbine's own needs. .