DE3304292A1 - METHOD AND DEVICE FOR REGULATING NETWORK FREQUENCY BREAKINGS IN A SLIDING PRESSURE-USED STEAM POWER PLANT - Google Patents

Description

BROWN, BOVERI & CIE AKTIENGESELLSCHAFT Mannheim February 7, 1Q83

Mp. No. 509/83 ZPT / P3-Sf / Bt

Method and device for regulating network frequency drops in a sliding pressure-operated steam power plant block

The invention relates to a method and a Vorrich- _"n processing for correcting system frequency declines at a gleitdruckbetriebenen steam power plant unit according to the preamble of claim 1.

Such a method is known from DE-PS 9 ^ 3 053. This patent specification assumes that in steam power plants that work with reheating of the steam, steam states arise in the steam system, which make good frequency driving impossible, unless you use the uneconomical nozzle or Applying throttle control. To avoid these difficulties, it is proposed that one be installed in the condensate pressure line built-in control valve to operate and thus the condensate flow through the heated with bleed steam Interrupt the preheater. As a result, more working steam is available in the turbine, so that this can deliver the requested higher performance. For loading

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acceleration of the control process is also provided, To temporarily close all or part of the valves in the bleed steam lines of the turbine. Unfortunately, however the power increase of the turbine that can be achieved with such a condensate stop depends on the momentary driven power of the power plant unit.

The operators of power plants demand that the power control in the interconnected network must comply with certain minimum conditions, both in terms of speed and in terms of amount. These requirements are mentioned, for example, in the publication "Power control in the network. Today's behavior of active power control and future requirements", published by the Deutsche Verbundgesellschaft eV (DVG), Heidelberg, November 1980 the network frequency must be at least 5% of the power plant unit's nominal power,

2Q with half of the performance increase already after

- 5 seconds, the full increase in performance after 30 seconds must be available. These and the other requirements are referred to below as "DVG network requirements". Current systems with condensate stop and

pure sliding pressure operation are not able to achieve this 25

To meet DVG network requirements.

From the magazine "VGB Kraftwerkstechnik", issue 8, August 1982, pages 656 to 665 is a concept for a Block control with frequency support in the operating mode "natural sliding pressure" has become known, in which the electrical power is regulated via the steam generation and via the turbine regulator the damper inlet valve is opened or throttled in front of the turbine. Beige-

_ ,. targeted changes in performance by adjusting the basic

Setpoint of the block output or in the event of heating faults

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the block should then behave as in the "natural sliding pressure" operating mode. In the event of a frequency deviation on the other hand, when the inlet valve of the turbine is initially throttled, the storage effect is reduced - The steam generator is used without delay by regulating the valve opening, so that the delay time of the steam generator is bridged. A basic setpoint of the position is used for the sliding pressure range "of the intake valve set. This required power-dependent The throttling of the inlet valves must be between 10/6 and 20% if the DVG requirements for coal-fired power plant units required power increase in the power control range from $ 100 to 45% should be guaranteed. This throttling means

“_ Has a heat loss of 0.45 to 1.1 / 6, which is no longer justifiable with today's systems. In addition, the familiar concept goes away from the fact that in a condensation turbine there is a linear relationship between steam pressure, valve opening and

«Λ electrical power exists. However, this only applies to the steady state.

From the magazine "VGB-Kraftwerkstechnik", April 1971, pages 151 to 164 is a power control by Kon-

-_ Densatstopp for a block power plant for sliding pressure operation 25th

known with coal firing. There is a controllable one between the cold water storage tank and the low-pressure preheater line Arranged feed pump, which makes it possible to stop the condensate flow in a few seconds or again to start fully. Since this system does not have the possibility to connect the lines for the bleed steam to the preheaters to block it is not able to meet the DVG network requirements.

Based on this prior art, the present invention is based on the object of providing a method of

Specify the type mentioned at the beginning, which makes it possible to comply with the DVG network requirements and at the same time to operate the power plant unit with minimal heat losses.

This object is achieved by the characterizing features of claim 1.

The advantages of the invention and further refinements thereof emerge from the subclaims in conjunction with the following description of an exemplary embodiment based on the drawing.

Show it:

Fig. 1 is a schematic representation of a coal-fired, sliding pressure operated steam power plant blocks with the associated control and regulation system,

Fig. 2 shows the time course for the activation of the resulting adjustment reserve in accordance with the DVG

requirements,

3 shows the time-dependent processes when regulating a drop in the network frequency when the power plant unit was operated at ^ 0% of the nominal output and

Fig. 4 shows the time-dependent processes when regulating a drop in the network frequency when the Power plant unit operated at $ 100 of nominal power.

In Fig. 1 you can see a power plant block with a

Coal-fired boiler with a small storage volume, to which the fuel is fed via a regulated feed device 2. Of the boiler 1 and in the ftberhitzer 3 na witnessed high pressure steam ER passes via a first controllable inlet valve 4 in the high-pressure part of a steam 5.1

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turbine. Via a reheater 6 and a second, controllable inlet valve 7, the steam reaches the Medium pressure part 5.2 and then into the low pressure part 5.3 of the steam turbine. On the medium pressure part 5.2 are a bleed steam line D and G and on the low pressure part 5.3 bleed steam lines E are provided. At the turbine a synchronous generator 8 is flange-mounted, which emits the generated electrical energy into the network. The low pressure part 5.3 relaxed, leaving the turbine

Ι «Steam is condensed in a condenser 9 and with With the aid of a first condensate pump 10, conveyed into a cold condensate container 13. Via a main condensate pump 11, to which a control valve 12 for the minimum flow rate of the main condensate pump 11 is connected in parallel, the cold condensate is passed through a condensate control valve into a low-pressure preheater line 15.1 .... 15.η, whereupon it arrives in a feed water tank 17. The low-pressure preheater branch consists of one Chain of η heat exchangers, of which (n-1) are recuperative low-pressure preheaters and the nth is a mixing preheater is, which at the same time forms the feed water tank. The low-pressure preheater line 15.1 ... 15.η and 17 is in a known manner by means of bleed steam

fed from the turbine, but in the bleeding steam lines G, D, E shut-off devices in the form of rule-25

rotary flaps 16.1 ... 16. (n + 1) are installed. the end From the feed water tank 17, the boiler feed water is pumped back into the boiler 1 via a high pressure pump 18, whereupon the steam-water cycle begins again.

The control system for operating the power plant block described in this way consists of a power controller 21, the actual speed η of the turbine from a measured value transmitter 22 and the actual value from a power transmitter 23 the electrical power P can be supplied. Of the

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Setpoint P3 is specified by a setpoint generator 25, where this value Ps is replaced by a correction value PfjR> which is supplied by a correction value transmitter 24 can be corrected. Ps and Pjjr together form the target value PfT ^ for the power plant unit output P ^ W · The controller 21 generates an actuating signal Y for the position of the first inlet valve 4 and an actuating signal Z 'for the position of the second inlet valve 7. In the control system, only the signal Y for the position of the first inlet valve 4 evaluated further. The control signal Z is dependent on the control signal Y, the storage effect of the reheater 6 being taken into account will.

The control system also contains a device 31 for detecting drops in the network frequency f. In addition to the actual value of the network frequency f, the turbine speed η and the position Y of the first inlet valve 4 is also the setpoint-actual value difference the position Y of the inlet valve 4 is supplied. The task of the device 31 is to recognize whether it The measured deviations of the network frequency f from the synchronous frequency fg, e.g. 50 Hz, only differ by small, statistical network frequency fluctuations - so-called

_o - see - acts that can be corrected using conventional methods, or stronger, longer-lasting drops in the network frequency, for example as a result of an overload of the network, which are corrected with the aid of the method according to the invention. In the latter case, the device 31 generates an output signal with which the condensate stop and the bleeding steam stop are controlled. The device 31 also generates an output signal, which acts as an adaptive signal, and to the power controller 21, to an inlet valve position controller 41 to be described below and via line B - to a

writing limit condensate flow control 101 acts.

The inlet valve position controller 41 is the actual value of Value Y, i.e. the position of the first inlet valve 4, and either a setpoint value via a changeover switch 44 precalculated position setpoint Yfj from a "Setpoint generator 42 or a corrected, also precalculated position setpoint Y-j from a setpoint generator 43 supplied. It should also be mentioned here that switching between the two setpoints - as well as the switchings to be described later in a different context - not only as shown in the drawing, can take place discontinuously with the help of a mechanical switch, but also after a time-dependent, continuous function.

The difference between the nominal value Yjj or Y-] and the actual value Y calculated in the inlet valve position controller 41 the inlet valve position acts first on the device 31, where it in a manner to be described and manner influences their output signal, and secondly on a fuel regulator 51, which is dependent on

the amount of fuel 25 measured in an actual value transmitter 52

a fuel feed station 53 controls.

If, as shown in the drawing, the pressure ρ {ζ of the steam upstream of the superheater 3 is measured in a pressure sensor 45, this steam pressure can be used as an auxiliary control variable to control the fuel quantity regulator 51 in the manner of a cascade control. This makes use of the fact that an increase or decrease in the vapor pressure p _{K is} the fastest measurable reaction of the power plant unit to an increase or decrease in the amount of fuel. The change in electrical

Power P follows with a considerable delay.

The amount of feed water stored in the feed water tank 17 is an important variable. For this reason, the level measured in a transducer 62 in a feedwater tank level controller 61 is compared with either a normal level% from a setpoint generator 63 or a reduced level H2 from a setpoint generator 64, both setpoint generators 63, 64 via a Changeover switch 65 are switchable. The output of the feedwater tank level controller 61 influences a controller 91 for regulating the position of the condensate control valve 14 such that the level in the feedwater tank 17 never falls below the minimum level H _1n ^ _n and never above it

, _ the normal level Hm increases.
Ib "

As already mentioned, the regulator 81 is used to regulate the position of the shut-off elements 16.1 .... 16. (n + 1) and the regulator 91 for regulating the position of the condensate control valve 14 by the device 31 for detecting network frequency drops is supplied with the desired position value X, the desired position value X being supplied with the aid of a switch 72 can also be placed on ground potential, which means "low-pressure preheater line fully open".

·.

The regulators 81, 91 are also supplied with a correction variable that comes from a comparator 82 at which Input again measured values from measuring points 83.1 ... 83.η issue. The measuring points 83.1 ... 83.η measure the thermal vision Stresses in the low-pressure preheaters 15.1 ... 15.n, which occur with the various thermal loads the low-pressure preheater - condensate flow stopped, condensate flow continuously regulated, condensate flow fully open - occur. With the help of the

__ correction variable, controllers 81 and 91 are synchronized in this way

nized that the amount of bleed steam exactly to the

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The amount of cold condensate that is flowing right now is adjusted so that the thermal stresses are within specified, permissible limits remain.

The controller 91, the condensate flow valve 14 with a position signal Xy is supplied, the output signal of a limit condensate flow controller 101 is also supplied fed. This controller 101 forms the setpoint / actual value comparison for the limit condensate flow m ^, where the The actual value is measured by a measuring transducer 102 and the setpoint is either a normal value from a setpoint transducer 103 or a reduced setpoint m ^ 2 from a setpoint generator 104, the setpoint values being switchable with the aid of a switch 105.

The controller 91 for regulating the position of the condensate flow valve 14 also emits an output signal X-], which the control valve 12 for the minimum flow the main condensate pump 11 then opens with lead when the condensate control valve 14 is closed quickly. This not only ensures a perfect puncture the main condensate pump 11 required minimum delivery rate is observed, but rather a pressure surge effectively avoided in the condensate pipeline.

The arrangement of the condensate control valve also serves to avoid pressure surges in the low-pressure preheaters 15.1 ... 15.η 14 in front of the first low-pressure preheater 15.1.

In normal operation, the control valve 12 is for the Minimum flow rate of the main condensate pump 11 as a function of the difference between an actual value of the condensate flow rate mg and mg measured in a measuring transducer 93 controlled by the setpoint coming from a setpoint generator 92.

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In principle, it would also be possible to replace the condensate control valve 14 with a speed-controlled condensate pump with short positioning time. The control procedure still to be described is not changed by this.

The control system also contains a switchover logic 71, which is controlled by (dashed lines) Lines are supplied with logical input signals and

IQ which also emits logic signals at its output. The input variables of the switching logic 71 come from the power controller 21, from the cold condensate tank 13, the maximum level H _{max of} which is evaluated, and the feed water _{tank 17, the minimum level Hj n} ^ _n and a reduced normal level Hg being evaluated. At the output of the switchover logic 71, a first output signal A appears, which actuates the switch 72 and the switch 105, and an output signal C, which actuates the switch 44.

Fig. 2 shows the time course for the activation of the resulting adjustment reserve Δ P / Pn in accordance with the DVG requirements. The power plant block must be designed for an adjustment range of the primary control of at least 5% of the nominal output. In fossil-fired power plant blocks, for which the control method according to the invention is designed, a power change rate should be achieved within this setting range that makes it possible to increase at least half of the setting range - corresponding to $ 2.5 - within 5 seconds and the entire setting range within 30 seconds drive through. These DVG requirements are very strict for fossil-fired power plant units. They are so sharp because of the power

3g work units of a company in general not all contribute to primary regulation, e.g. because some

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Blocks are operated in pure sliding pressure. The requirements for each individual primary-controlled block with regard to the setting range and the rate of change in output must therefore be higher than the average values for the resulting setting reserve. For this reason, hydropower plants or nuclear power plants, which achieve higher rates of power change than conventional thermal blocks, are currently used for the actual primary control; Fossil-fired power plant blocks regulated according to previous methods would - as already mentioned - require constant throttling of the inlet valves between '\ 0% and 20%, which, however, result in heat losses of Ο, 4.5% to £ 1.1, which the power plant operators hardly ever do can tolerate.

The control method according to the invention will be explained in detail with reference to FIGS. 3 and 4. 3 shows the behavior of the power plant block and the control and regulation system when a network frequency drop occurs when the instantaneous power Pq of the power plant block is equal to 40 $ of the nominal power Pjj. FIG. 4 shows the behavior when the network frequency drop occurs when the instantaneous power Pq of the powerful plant block is equal to the nominal power Pfj. The time t is plotted in minutes on the x-axes. On the y-axes are the network frequency f in the top diagram, the power plant actual power P, the fuel power Pg and the power PfjDV of the low-pressure preheater branch in the middle diagram, and in the lower diagram the position Y of the first inlet valve 4, the Position Xy of the condensate control valve 14 and the pressure PpD of the live steam upstream of the inlet valve 4 are plotted. Δ f is the size of the network frequency drop compared to the network synchronous frequency fg. Pqo =? 0 ⁺ °> ° 5 · Pfj is the according to DVG requirements by 5% of the nominal

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stung increased performance. Xpj is the normal position of the condensate control valve 14. yjj is the normal position of the first intake valve 4. Y _m ax denotes the maximum open position of the intake valve. 4

If one looks first at FIG. 3, one recognizes that at the point in time t ₀ ′ there is a drop Af in the network frequency f with respect to the synchronous frequency fo, which exceeds a certain value and lasts for a long time.

Such a network frequency drop usually occurs when the network is overloaded due to the connection of an above-average number of consumers or due to the failure of one or more power plant units. In the method according to the invention, in order to compensate for such larger network frequency drops, the inlet valves are usually first opened and then the condensate flow is more or less stopped. However, if the frequency drop is so great that it can no longer be corrected by moving the inlet valves alone, the low-pressure preheater section is switched off simultaneously and in parallel. In the operating state Pq = 0.4 · Pjj, the inlet valve 4 is initially in a normal, precalculated position Y ^ which ^{is e} ^ wa compared to the maximum value Ymax

-_ 5% is throttled. With this throttling, the 25th

The performance deficit of the condensate stop is compensated for, in order to achieve the 5/6 power increase required by the DVG requirements. When the The grid frequency drop Af at time tg is

OQ half the inlet valves 4.7 up to the maximum value 'Y ^ ax opened and at the same time the condensate control valve 14 moved down from its normal position value X ^ to zero. At the same time, the shut-off devices 16.1 ... 16. (n + 1) in the tapping steam lines G, D, E are synchronized closed to the condensate control valve 14, but this is not shown separately in the drawing.

In order to prevent an impermissible surge of water under pressure in the pipeline, the 'is parallel to the main condensate pump 11 switched control valve 12 opened with a lead.

- When the inlet valves are opened, the live steam pressure ppi) drops and the power plant unit goes into the "natural sliding pressure" operating mode. The power P delivered to the network increases by 5% of the nominal power in accordance with the DVG requirements, whereby the power requirement

IQ increased by switching off the bleeding steam lines until the maximum value PfjüVmax is exhausted. At the same time, the fuel output Pg is increased. At time t- | If the fuel output Pg exceeds the power plant unit output Pqo> corresponding to the network frequency drop Af, ^{so that the} position Xy of the condensate control valve can be opened beyond the normal operating value Xjj. At time tj, the setpoint Y _n is also switched to the other setpoint Yj. The refilling of the partially emptied feed water tank 17 begins and lasts until time t ^. As will be described below, because of the intervention of the limit condensate flow regulator 101, the inlet valve ¹ J must be throttled slightly and briefly in order to regulate any excess power to the turbine.

The throttling of the inlet valves 4,7 and, if necessary 25th

the resulting disproportionate rise in the live steam pressure ppß are used to accelerate the adjustment of the fuel output Pg to the new steady state. At time t2, the reduced level ^ Z * ^m feed water tank is reached, so that the previously blocked condensate stop can be released.

At time t3, the refilling of the feed water tank to the normal level H _{n is} ended. The condensate

__ control valve and, synchronously, the shut-off devices in the if

Tap lines are set to the normal operating value X _n

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reset, likewise the inlet valves to their normal operating value Yn j, the setpoint value being switched back from the increased setpoint value Y-], which generally _{corresponds to the maximum value Y max} , to the normal value Yjj corresponding to the current power plant output. At the same time, the amount of fuel _{is adjusted to its value corresponding to the new power plant output P 0} Q, whereupon the live steam pressure ppp is also adjusted to its new steady-state value.

To the duration of the described control process as possible

To keep it short, when the limit condensate flow controller 101 intervenes, the original setpoint Y ^ for the position of the inlet valves 4,7 is set to a higher _ις setpoint Y- | switched. This prevents the inlet valves 4, 7 from being closed because of the negative control deviation still pending at the power regulator 21, which, as mentioned, would unnecessarily increase the thermal losses of the power plant unit. The strong throttling of the inlet valves 4, 7 would also inevitably result in an unnecessary increase in the live steam pressure which, after the completion of the refilling of the feed water tank 17, would in turn mean a relatively large pressure reduction.

Fig. 4 shows the behavior of the power plant block and control system when the instantaneous power Pq 100? £ corresponds to the nominal power P ^ of the power plant block. This can be seen because the intake valve is already at the maximum value Y _ma x. The value Y remains first on Y _m ax> while the position XY of its normal operating value X ^ very quickly shuts down to zero.

With the closing of the condensate control valve 14 and the shut-off elements 16.1 ... 16. (n + 1), the power P increases

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Turbine synchronous with P ^ dv ^on * At the same time, more fuel is fed to the boiler via the fuel regulator, so that Pg also rises. However, this process is much slower.

As soon as the steam output of the boiler increases due to the increased addition of fuel, the condensate flow can be released again accordingly. PfjDV decreases synchronously with the increase in Pg. At the same time, Xy increases again. As soon as the fuel output Pg exceeds the unit output Pqq, which has increased by 5% , at the time ty , the boiler can output more output than the power plant unit has to supply into the network. This excess power is compensated by the fact that the condensate flow mg through

_<He the low-pressure preheater 15.1 ... 15.η over the normal Io

value is increased; the condensate control valve 14 is over the normal position value Xjj opened. The excess of performance from Pg via Pqo is now due to an increased derivative balanced by bleed steam from the turbine.

The refilling of the internal

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follow the condensate stop partially emptied feed water tank 17. Since the actually flowing condensate mass flow mg is determined by the limit flow controller 101 and the limit flow depends on the

__ current power output P of the power plant unit, there could be an excess output of the boiler over the required turbine output. This excess of power is compensated by briefly throttling the inlet valves 4.7 at time ti. For this reason the live steam pressure ppp also rises from t- | faster on, than it would correspond to the pure sliding pressure operation. The throttling of the inlet valves 4,7 also acts like already described, on the fuel regulator 51 with a view to faster control of the amount of fuel to a steady-state value.

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As long as the feed water tank 17 continues to be refilled, the control is blocked in such a way that a condensate stop, for example if the frequency drops again, cannot be initiated. However, as soon as the level in the feed water tank 17 reaches the reduced level Hz _{at time t 2, the control is enabled.} However, refilling continues until the normal level% is reached; this is the case at time t3. At time t- $ , these will be

IQ condensate control valve 14 fed in position by reducing the value Xy on xfj and the amount of fuel to the value of the instantaneous power plant block power PQO ^re duced ~. An excess of steam power compared to the power P currently delivered to the network is compensated for by briefly throttling the inlet valves 4, 7. As a result of this throttling, the pressure PpD of ^the live steam also rises briefly until, as a result of the reduced fuel output Pg, it adjusts to its new value corresponding to the power plant unit output Pqo increased by 5%.

At the moment when there is either a positive control deviation again on the power controller 21 - the actual value is smaller as a setpoint - pending or the actual position of the inlet valves 4.7 the value of the original Setpoint Y ^ is reached, the maximum position setpoint Y-] is switched back to the normal setpoint Yjj. Thus, after the end of the regulating process, the control and regulating system is responsible for regulating a further one Grid frequency drop is fully available again.

During the so-called condensate stop, the boiler 1 is supplied from the feed water tank 17, while the feed water tank 17 itself is not refilled. If prolonged this mode of operation, a minimum water level H _m i _n may ER in the feedwater tank 17

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be enough . In this case, the condensate stop must be ended immediately, regardless of the needs of the power regulator 21. This is caused by the switching logic 71, which immediately switches over to the "refill" operating mode already described. In this case, however, the condensate flow is only slightly increased above the value that corresponded to the current power setpoint in normal operation. So it is not the limit flow rate but a reduced flow rate according to the target value m ^ switched on. When the level in the feed water tank 17 _{has reached the level H2, which is slightly higher than the minimum level H m} j_ _n , the level controller 61 takes over the control of the condensate control valve 14 so that the feed water content is kept at this level. This somewhat increased level H2 is regulated until the power P is brought to the required setpoint Pqo by the increase in the fuel power Pg. Once this has been achieved, the filling process is enabled in accordance with the "refill" operating mode described above. In this way, the proper operation of the power plant block is guaranteed and at the same time the power deficit that inevitably occurs due to the interruption of the condensate stop is kept as small as possible.

As already mentioned at the beginning, the method according to the invention is used to regulate larger, longer-lasting network frequency drops. The great advantage of the method according to the invention is that at the load point Pq = Pn no throttling of the inlet valves is necessary and that at the load point Pq = 0.4 * P ^ only about 5% throttling is necessary to. To meet the strict DVG requirements for a sliding pressure-operated, coal-fired power plant unit equipped with a once-through boiler with reheating.

To compensate for the small, stochastic network frequency deviations mentioned, the inlet valves are in practice also throttled slightly, ie by approximately 2% , at the load point 10OiS Pjj. This is taken into account when calculating the setpoint values Y _n and Yj for the position of the inlet valves 4, 7.

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Claims (12)

509/83 -tf: -. Expectations .} Procedure for compensating for network frequency drops in a sliding pressure operated steam power plant block containing a boiler with slow firing and a small storage IQ chervolume, a multi-stage steam turbine with reheating of the steam and bleeding lines, a throttled inlet valve in front of the steam turbine, a throttled inlet valve behind the intermediate _1S superheater, a main condensate pump,
a cold condensate tank,
- a low-pressure preheater line, a condensate control valve in the condensate line of the low-pressure preheater line, a feed water tank and Shut-off devices in the tapping lines from the turbine to the low-pressure preheater line, in the event of sudden loads on the steam turbine, the -_ low-pressure preheater section is switched off by the condensate control valve in the condensate line and the shut-off devices in the tapping lines are completely or partially closed, and if the required boiler output is exceeded or the steam turbine is relieved, the condensate control valve is opened further, characterized in that that initially the inlet valves (4, 7) are constantly open and the low-pressure preheater line (15.1, ... 15.n, 17) are continuously switched off, whereby the condensate control valve (14) and the shut-off devices (16.1, ... I6. (N + 1)) are closed synchronously, 509/83 that at the same time the fuel supply to the boiler (1) is increased correspondingly, that when an excess of steam power occurs, the low-pressure preheater section (15.1, ... 15.η, 17) is continuously switched on again by the condensate control valve (14) and the shut-off elements (16.1 , ... Ιβ.η) be opened synchronously, "that then the condensate control valve (1 ¹ O via the corresponding to the current turbine output 1Q operating position is also opened so that at the same time the fuel supply to the boiler (1) continues to be increased when the inlet valves (4,7) are fully open,
that the setpoint for the position of the inlet valves (4,7) is switched to a second higher value (Y-]), whereby the fuel supply is set to a new steady state, that when the feed water tank (17) is refilled, the condensate control valve (14) is brought into its operating position corresponding to the current turbine output, the inlet valves (4, 7) are throttled according to the required turbine output, the setpoint for the position of the inlet valves (4,7) to its normal ₂ _ value (Yn) is switched back, whereby the normal value (Yn) depends on the increase in turbine output that can be achieved by switching off the low-pressure preheater line (15.1 ...), and the fuel supply is regulated to this definitive steady state. 2. The method according to claim 1, characterized in that the opening of the inlet valves (4, 7) and the Close the shut-off devices (16.1, ... I6.n) and the condensate control valve (14) take place simultaneously. 33S42S2 ■ 509/83 "J- 3. Method according to claim 1 or 2, characterized in that the position (Z) of the inlet valve (7) downstream of the reheater (6) depending on the position (Y) of the inlet valve (4) upstream of the steam turbine will. 4. The method according to claim 1, 2 or 3, characterized in that the thermal stresses in the low-pressure preheater line (15.1 ... 15.11.17) are measured and that the opening and closing of the shut-off devices (16.1 ... I6.n) and the condensate control valve (1 ¹ I) is synchronized so that the thermal stresses do not exceed the permissible values. 5. The method according to claim 1, characterized marked-15 net that the second setpoint (Y ₁ ) of the controller (41) for the position of the inlet valves (4, 7) is switched to maximum open after opening the condensate control valve (14). 6. The method according to claim 1 or 5, characterized in that after refilling of the feed water tank has ended (17) the nominal value for the position of the inlet valves (4, 7) at its calculated normal value is switched back as soon as either the actual value (Pist) of the power plant unit output below the setpoint decreases or the actual throttling of the inlet valves (4, 7) reaches the calculated value (Yjj). 7. The method according to at least one of claims to 6, characterized in that when the water level (H) in the feed water tank (17) drops to a minimum level (H _m i _n ) and when the low-pressure preheater line (15.1, .. November 15, 17) the low-pressure preheater line (15.1, ... 15.n, 17) 509/83 I / is switched on again, then the condensate control valve (14) is opened slightly beyond the operating position corresponding to the current boiler output, g - when a _{level (H2) which is slightly higher than the minimum water level (H m} j [ _n ) is reached, the condensate control valve (14) is controlled so that this level (H2) is maintained until the turbine output (P ^ gfc) reaches or exceeds its setpoint due to the effect of the increased fuel supply and then the actual refilling of the feed water tank (17) is carried out. 8. The method according to claim 7, characterized in that the power control by switching on and off of the low-pressure preheater line (15 1, ... 15.n, 17) is released again as soon as a specified, sufficient water level (H2) in the feed water tank (17) has been reached, which, however, is still below the value (%) of the level control in normal operation. 9. The method according to at least one of claims 1 to 8, characterized in that the fast „_ Close the condensate control valve (1,7) a control valve (12) for the minimum flow of the main condensate pump (11) is opened with a lead. 10. The method according to at least one of claims to 9, characterized in that the fuel supply is not only dependent on the target / actual value difference of the position (Y) of the inlet valves (4,7) but also as a function of the measured value of the vapor pressure (p _K ) is regulated behind the evaporator of the boiler (1). 11. The method according to at least one of the claims 509/83 to 9, characterized in that the fuel supply is not only dependent on the target / actual value difference the position (Y) of the inlet valves (4,7) but also as a function of the measured pressure drop across the Inlet valves (4, 70 is regulated. 12. Device for performing the method according to claims 1 to 11, characterized by a device (3D for the detection of break-ins ^ q the mains frequency (f) and to control the controller (81,91) for the shut-off devices (16.1 ... 16.n) and des Condensate control valve (14), a power regulator (21) which adjusts the inlet valves (4,7) as a function of a power _{setpoint (P K} ) and the actual values of the electrical power (P) and the turbine speed (n) and at the same time the device (31) for detecting intrusions the mains frequency (f) and an inlet valve position controller (41) influences the inlet valve position controller (41), the setpoint of which can be switched between two setpoint generators (42, 43) and which supplies a fuel controller (51) with a setpoint,
the fuel regulator (51), which controls the amount of dem __ Boiler (1) regulates the fuel supplied, the regulator (81) for regulating the position of the shut-off devices (16.1 ... I6.n) in the tapping lines (D, E, G) of the turbine (5.2,5.3),
the controller (91) to regulate the position of the condensate control valve (14), a feed water tank level controller (61) whose setpoint is between two setpoint generators (63,64) is switchable, and the controller (91) for regulating the position of the condensate control valve (14) as a function controls from the level in the feed water tank (17), 509/83 a controller (101) for the limit condensate flow (nifr), the setpoint of which can be switched between two setpoint generators (103,104), and a switching logic (71) that switches the setpoints for the controller (81,91) to regulate the position of the Shut-off elements (16.1 ... 16.n) or the condensate control valve (14), for the controller (101) for the limit condensate flow rate (m ^) and for the inlet valve position controller (41), depending on the capacity controller (21) and the levels (H _m i _n, Hz) in the feedwater tank (17) or (H _max) in the cold condensate tank (13).