SU444890A1 - Control system of the boiler turbine generator unit - Google Patents

Description

one

FIELD OF THE INVENTION The invention relates to a power system and can be used in block-type power plants, where turbines have a nozzle vapor distribution .5

Known are the control systems for the boiler-tsgrbina-generator unit, which contain a power regulator whose inputs are connected to a setpoint. power tick and generator active power sensor, and the output is connected to a turbine synchronizer; a steam pressure regulator, to the inputs of which a pressure sensor is connected, a steam in front of the turbine and a setpoint generator with a power supply through a master pressure transmitter and the output is connected to a boiler regulator; and a differentiator connected between the power setting device and the vapor pressure regulator.

Such systems do not always fully optimize the efficiency of the unit, especially when deviations of some installation parameters.

The purpose of the invention is to improve the efficiency of the unit,

For this, an extreme regulator with sensors of the optimality criterion, such as efficiency, unit, is additionally connected to the input of the master converter, and a switching unit is provided at the input of the pressure regulator, equipped with an intermediate element, to the inputs of which the master transmitter and the pressure sensor are connected. and the output is connected to the executive relays in the input circuits of the pressure controller, and the forcing channel with an additional differentiator, the output of which is connected to a power output relay.

Fig I shows a block load control system; FIG. 2 shows an example of a master converter; in fig. 3 is an example of a switching unit; in fig. 4 - power dependence curve - the optimal allowable position of the servomotor

bins; in fig. 5 - power dependency curve - optimal allowable pressure; Fig. 6 shows an oscillogram of the transient process of the control system. five

The unit control system consists of a conventional power control circuit, a vapor pressure control circuit, an extremum controller and a switching unit,

The power control circuit (see FIG. 1; consists of sensor I;

active power generator 2 and setpoint 3 power connected to the inputs of the controller 4 power, 15 stroke which is connected to the synchronizer 5, influenced by a hydraulic system (not shown) through the servo motor 6 on the control valves 7 of the turbine 8, 20 The output of the setting device 3 is also connected to the input of the setting converter 9, which is included in the steam pressure control circuit, and through the differential; Ator 10 and switching unit II - 25 to the input of pressure regulator 12 -; ra. One of the inputs of the controller 4 is given a signal from the switching of the second block II,

The steam pressure regulating circuit contains a steam pressure regulator 12, to the inputs of which, via switching unit II, signals of pressure sensor 13, differential valve 10, driver 35 and unit 3 for power, arrive. Through the switching unit II, the controller 12 is closed by a feedback feedback.

The output of the regulator 12 is connected 40 to the input of the regulator 14 of the boiler capacity. Such a regulator in specific cases can be a fuel consumption regulator or a power regulator with an impact on the capacity of the feed pump. You can build a circuit with a power regulator that affects only the boiler control valves, but the efficiency of optimizing the vapor pressure at This will be reduced. The regulator 15 also includes the medium temperature controller 15 at the intermediate point of the steam and water system of the boiler. In addition to the usual signals not shown in the drawing, the signal from the master converter 9, passing through the corrective device 16, also comes to the input of the VTO regulator. In the case when the regulator 14 is a fuel consumption regulator, the regulator 15 affects the flow rate feed water. If the controller 14 controls the flow of feed water, the functions of controlling the fuel consumption are assigned to the controller 15.

The input of the extreme regulator G7 is supplied by the signals of the sensors necessary for calculating the optimality criterion, for example, k, n, d of the block, and the signal from the output of the regulator 17 is fed to one of the inputs of the master converter 9,

The signals from setpoint 3 and extreme controller 17 are connected to the inputs of reference element 18 (see, fig. 2), from which the signal goes to relay 19 with contacts 20 and 21. The signal from the element also goes to amplifier 22 and 20 - to amplifier 23 having linearity zones and output limiting zones. At the same time, the linearity zones of amplifiers 22 and 23 are shifted in such a way that the start of operation of amplifier 22 coincides with the input signal when amplifier 23 enters the limiting zone (before that, the signal of amplifier 22 is zero). Contact 20 translates the operation of the circuit from amplifier 23 to amplifier 22. The output signals of amplifiers 22 and 23 are connected to the input of the adder 24, the output of the adder 24 is fed to the switching unit II and the correction device 16 Contact 21 receives a signal from an external source to one of the inputs switching unit 11,

The switching unit II is intended to temporarily block the operation of the steam pressure regulator 12 and temporarily force the power regulator 4.

The contact 21 of the relay 19 (see Fig. 2) is connected to the input of the differentiator 25 (see Fig. 3), and the output of the differentiator 25 is connected to the input of the modulator 4, as well as to the rectifier 26. The signal from the rectifier 2man controls winding a relay 27 having a self-pickup contact 28, a normally closed contact 29 in the circuit from the pressure sensor 13 to the controller 12, a normally closed contact 50 in the circuit from the adder 24 to the regulator 12, a normally closed contact 31 in the chain from the differentiator 10 to the controller 12 and normally open contacts 32 and 33 in the feedback circuit of the regulator 12 and in the circuit from the rear tchika torus 3 to the regulator 12, respectively, in the change-over switches "block sch1y

Also included is an adder 34, which receives signals from sensor 13 and adder 24 in antiphase, Adder 34 controls the coil of relay 35, which has contact 36, which breaks a self-pickup circuit from an external source through relay diode 37 to contact 28 of relay 27,

In accordance with the dependence of the power L - the optimal allowable pressure P (cm, fig, 5) one can distinguish three main modes of operation of the system: with a constant vapor pressure, with an increase in the specified vapor pressure with increasing load and with a sharp drop in pressure with increasing load.

The first mode of operation coincides with the mode of operation of a conventional unit load control system. When the setting unit 3 changes the load, controller 4 begins to work first, moving synchronizer 5 and servo motor 6c to 1 control valve 7. Turbine 8 receives a new load, differentiator 10 sends an early signal to controller 12 through switching unit II and provides an increase in pickup block. The regulator 12 senses the change in steam pressure and restores the pressure to the previous level by acting on the regulator 14 of the boiler capacity,

The second mode is characterized in that the change in the load reference from the setpoint 3 in the transformed form also enters the vapor pressure regulator 12. As a result, the recirjfeTop 12 sets a new vapor pressure. The change in the pressure task also plays the role of an additional advance signal, and therefore the acceleration of the block in this mode increases as much.

Optimization of the valve position / g turbine ratio (see FIG. 4) and the pressure of fresh steam is performed by power and steam pressure regulators by joint operation of these regulators while changing the target power L /, for example, to / k 2 is illustrated by the waveform in FIG. 6, When changed. Research institutes set OT / KJ to // 2 regulator

4 power almost instantaneously (compared to the pressure regulator) monitors the task, opening the turbine ri valves. At the same time

the signal of the power setting from the setting device 3 through the setting of the converter 9 is supplied to the steam pressure regulator 12, changing its ycTaBiqr in accordance with the working schedule of the charging converter In FIG. 6), the reference generated by the specifying converter 9 is shown in FIG. 6 by line P ,

The vapor pressure at the first moment of change (increase) in the power of the turbine unit drops (line P at

i, 6), and then, as the new installation is adjusted by the regulator 12 and the output of the coaggregate is increased, the pressure begins to rise. Since the mismatch between the reference signal and the actual input signal at the input of the regulator is 12 veiko, the latter continues to increase the performance of the boiler. There is a tendency to increase the load of the generator above the setpoint, the regulator 4, trying to keep the load unchanged, begins to gradually cover the valves 7 of the turbine 8. in exact accordance with the area // t - / y P depending on the optimal allowable position of the valves on the load l (see Fig. 4)

When the operating conditions change (vacuum in the condenser, sampling values, etc.), the specified power value will be obtained when the valves position is different from the optimal one. Therefore, the initial dependence of the vapor pressure on the load adjusts the extreme regulator 17 in accordance with the actual value optimality criteria, for example, in accordance with k, p, d, turbine net or k, p, d, block. The value of the criterion of optimality of the controller 17 calculates the information received from the respective sensors. The regulator ensures the search for the maximum of the optimality criterion by acting on the input of the master converter 9

The effect of the regulator 17 is to restore the optimum valve position. The regulator 17 enters into operation with significant changes in operating conditions. The third one is characterized by the fact that at a certain and constant value of the load of the turbogenerator (cMoyt / 2 in Figs. 4, 5) and, accordingly, the constant performance of the boiler, it is necessary to make an automatic jump from one value of pressure to another. This transition is carried out by matching jumps in the position of the valves without a significant dynamic change in the load of the turbo generator and the boiler capacity. Since the steam pressure regulator 12 in this mode works falsely (when the signal of the power setter decreases, the signal of the master converter decreases, i.e. given vapor pressure is lower than its actual value), its action is blocked by means of switching unit II. For scrutinized drivers, the implementation of the master converter 9 and the switching unit II causes the third operation mode to occur when the relay 19 is triggered, when the signal of the comparison element 18 reaches the trigger level of this relay. At a small increase in the signal of the setting device 3 of power and the triggering of the relay 19, the latter by means of the contact 20 turns off the amplifier 23, changing the task setting to the controller 12 and the contact 21 delivers a jump-like signal to the input of the differentiator 25 (smtzhg Z), the relay 35 and the SBOIL contact 36 prepares a circuit for latching the relay 27 “The disappearing S1Gyal from the differentiator 25 is supplied to the power regulator 4, which leads to some re-adjustment on the load. The occurrence of a signal at the output of the differentiator 25 also triggers the relay 27g which, by contact 28, becomes self-picking, and contacts 29-33 blocks the operation of the vapor pressure regulator 12. The operation of the regulator is blocked by interrupting the regulator 12 by negative feedback by contact 32, breaking its input circuits by contacts 2 & -3I and connecting to the input signal of the setting power 3, In this mode, the output signal of the control 12 of the steam pressure corresponds to the setting signal of the control 3 power. Since the setting of the power controller 4 is temporarily increased by the differentiator 25 signal and exceeds the boiler capacity, the controller 4 starts opening the valves 7, acting on them through the synchronizer 5 and the servo motor 6. When the steam pressure becomes right |: the output signal of the accumulator 34 causes the opening of the relay 35, which by the contact 36 breaks the self-pickup circuit of the relay 27. By this time the output signal of the differentiator 25 can no longer hold the relay 27 in the on state, it opens the contacts 32, 33, 36, closes contacts 29-31 and thereby restores the switching of the pressure regulator 12. In the control system, a statish connection is provided from the master converter 9 to the medium temperature controller 15 at the intermediate point of the boiler steam line (via the correction device 16). This connection is necessary to compensate for the effect of a spontaneous change in the load of the boiler when it is transferred to a reduced pressure. With a decrease in pressure and a constant heat supply, the temperature of the vapor at the intermediate point of the tract drops. In the absence of static communication, the controller 15, being, for example, a fuel controller, would restore the temperature by increasing the load on the boiler. The static connection changes the task to the controller 15, ensuring, with the help of the correction device 16, the autonomy of the operation of the controller 15 from the action of the pressure optimization system. For example, as the set pressure decreases, static linkage decreases the set point temperature. Static synchronization is active in the second and third modes of operation of the block load control system. SUBJECT OF THE INVENTION The control system of the boiler-turbine-generator block comprising a power regulator, to the inputs of which the generator is connected and the generator active power sensor, and the output is connected to the turbine synchronizer. , steam pressure regulator, to the inputs of which the vapor pressure sensor in front of the turbine and the power gauge are connected

through the optimum pressure transducer, and the output is connected to the boiler controllers, and the differentiator, which is turned on between the power setpoint and the steam pressure regulator, is different from the fact that, with the efficiency of the unit, the extremum controller is additionally connected with sensors of the criterion of optimality, such as efficiency The unit has a switching unit at the input of the pressure regulator, equipped with a comparison element, to the inputs of which the transducer and pressure sensor are connected, and the output connected to the executive relays in the input pressure regulator circuits, and an additional differentiator, the output of which is connected About power control.

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