JP6704517B2 - How to operate a turbine generator - Google Patents

Description

The present invention relates to a method of operating a turbine generator.

A turbine-generator is here understood to be an assembly comprising at least one turbine, for example a steam turbine, for example a generator, for example a three-phase current generator or a three-phase alternating current generator, the turbine generating electricity. The latter generator generates a three-phase current or a three-phase alternating current that is fed into a power grid such as a power supply system.

Turbines may have overload valves that increase the absorption capacity of the turbine. Therefore, the power output of the turbine can be increased at a constant pressure. However, when the overload valve is opened, turbine efficiency is reduced. Therefore, the overload valve is supposed to open only in certain selected operating situations. Such operating conditions are low frequency or expensive electricity.

Therefore, the overload valve is opened with a fixed assignment for the opening of the live steam valve. In other words, the overload valve and the live steam valve are strictly and reliably connected. However, this tight and secure connection of the overload valve and the live steam valve entails a reduction in efficiency when the overload valve does not have to be opened.

Therefore, it is an object of the present invention to show how turbine efficiency can be improved.

According to the invention, in a method of operating a turbine generator having a turbine and a generator connected to the turbine, the generator supplies a three-phase current or a three-phase alternating current into the grid at a grid frequency. The turbine has a live steam valve and an overload valve,
Monitoring the grid frequency for frequency drops relative to the frequency target, and
Detecting the state of the live steam valve with respect to the open state;
Opening the overload valve in response to detecting the frequency drop and in response to the detected open state of the live steam valve;
Carry out.

Therefore, it is ensured that the overload valve is opened only when the live steam valve is fully opened and there is a frequency drop. Therefore, efficiency during rated operation can be increased and an overload valve can be used to dynamically increase the output of the turbine in the event of a frequency drop.

An indicator binary signal is generated in response to the detection of the frequency drop, a further indicator binary signal is generated in response to the detection of the open state of the live steam valve, and the operation of opening the overload valve The two signals are preferably combined with an AND element to generate the signals. Thus, it is ensured by simple means that the overload valve is opened only when the live steam valve is fully opened and there is a frequency drop.

For example, in response to an actuation signal, at least one output target value is compared to an actual output value to determine a control error, and an overload valve is opened in response to the determined control error. preferable. For example, the control error can be fed to the PI controller. Therefore, in the case of a frequency reduction, a particularly rapid and unbiased adaptation of the turbine output can be achieved. Additionally or alternatively, it may be prepared that the grid frequency is compared to a frequency target value and that further values for determining control errors are determined. The further value may be, for example, a measure of the power level required to stabilize the grid frequency. Therefore, control can be further improved.

The output target value is preferably compared with the actual output value to determine a control error, for example in response to an actuation signal, and the live steam valve is preferably opened in response to the determined control error. For example, the control error can be fed to the PI controller. Thus, a particularly rapid and unbiased adaptation of the supply of steam to the turbine can be achieved.

The grid frequency is preferably compared to a frequency target in order to infer the presence of a frequency drop. The grid frequency is here the frequency of the three-phase current or three-phase alternating current of the power grid. Therefore, the frequency reduction can be detected in a simple manner.

It is preferable that the value indicating the frequency decrease is determined by evaluating at least the grid frequency and the frequency target value, and that the frequency decrease is estimated when the value is larger than the limit value. Therefore, it is ensured that the frequency drop is not inferred inaccurately and that the overload valve is not opened unnecessarily, which would otherwise lead to reduced efficiency.

Preferably, the live steam sensor signal is compared to a threshold and an open state is inferred if the live steam sensor value is greater than the threshold. Therefore, it is ensured that an open live steam valve would not be inferred incorrectly and that the overload valve would not be opened unnecessarily, which would otherwise lead to reduced efficiency.

Furthermore, the invention comprises a computer program product and a device implementing the method.

In the text that follows, preferred embodiments of the method according to the invention are described with reference to the accompanying schematic drawings.

1 is a schematic diagram of a turbine generator having a turbine and a generator coupled to the turbine. 2 is a schematic diagram of a device for controlling the turbine shown in FIG. 1. FIG.

First, refer to FIG.

FIG. 1 shows a turbine generator 1. In this case, the turbine-generator 1 is considered to be a combination of rotating machines that help generate electricity. The turbine generator 1 is generally composed of a turbine 3 such as a steam turbine or a gas turbine, and a generator 2 driven by the turbine 3.

In the present exemplary embodiment, turbine 3 is embodied as a steam turbine. Therefore, the turbine generator 1 in the present exemplary embodiment may also be referred to as a steam turbine generator. The turbine 3 has a high pressure stage 4, an intermediate pressure stage 5, and a low pressure stage 6.

Furthermore, FIG. 1 shows the live steam valve 7 and the overload valve 8 of the turbine generator 1.

The live steam valve 7 may be a throttle valve with which the supply of steam to the turbine 3 and thus the rotational speed of the turbine may be influenced thereby. In this case, the steam continuously flows through the high pressure stage 4, the intermediate pressure stage 5 and the low pressure stage 6 of the turbine 3. The turbine then drives a generator 2 which supplies a three-phase current or a three-phase alternating current at the grid frequency NF.

The overload valve 8 is arranged parallel to the live steam valve 7, but in the present exemplary embodiment it allows steam to be fed into the central region of the high pressure stage 4. In other words, when the overload valve 8 is opened, the input stage of the high pressure stage 4 is bypassed and the remaining stages of the high pressure stage 4 have a relatively high steam pressure in order to achieve an increase in the output of the turbine 3. Supplied. In contrast to the present exemplary embodiment, when the overload valve 8 is opened, the steam of the high pressure stage 4 of the turbine 3 is fed directly to the medium pressure stage 5 in order to achieve an increase in power output if necessary. Things can also be prepared.

Still referring to FIG.

FIG. 2 shows a device 9 for controlling the turbine 3 of the turbine generator 1.

The device 9 in the present exemplary embodiment includes an AND element 10, a characteristic curve element 11, a first PI controller 12, a second PI controller 13, a first comparator 14, and a second comparator 15. It has a subtractor element 16 and a changeover switch 17.

The characteristic curve element 11 is designed to read the value of the grid frequency NF and compare it with the frequency target value.

Based on the result of this comparison of the two frequency values, the characteristic curve element 11 determines the value WE. The value WE represents the difference between two frequency values, and in the present exemplary embodiment said value WE is an output correction value, which is the value of the output required to stabilize the grid frequency.

In the exemplary embodiment, the first comparator 14 compares the value WE with the limit value GW. The limit value GW has a magnitude of 0 percent in the present exemplary embodiment. If there is a deviation between the grid frequency NF and the frequency target value that is greater than 0 percent, a frequency reduction FA is inferred in the present exemplary embodiment.

The frequency down FA is a binary signal that, in the present exemplary embodiment, is a logical one when frequency down is present. Otherwise the signal is a logical 0. The frequency reduction FA is provided to the AND element 10 as one of two input variables.

In addition to the value WE, the actual output value LI of the turbine 3 and the desired output value LS are supplied as input variables to the subtractor element 16 and the control error RA is determined.

The control error RA is supplied as an input variable to the first PI controller 12, which makes the first valve control signal VS for actuating the live steam valve 7 available.

The open degree OG of the live steam valve 7 is detected by using a sensor (not shown). The openness degree OG is supplied to the second comparator 15 as a first input variable. The threshold value SW is supplied to the second comparator 15 as the second input variable. The threshold value SW has a magnitude of 99 percent in the exemplary embodiment. Thus, if the degree of opening OG exceeds 99%, ie the live steam valve 7 is fully opened, the second comparator 15 produces a binary signal of logic 1 for the open state ZU. Otherwise, the logic signal is 0.

The open state ZU is supplied to the AND element 10 as the second input variable.

When both the frequency lowering FA and the open state ZU are present, the AND element 10 supplies an actuation signal AS in the form of a binary signal of logic 1 which activates the changeover switch 17. In response to the operation, the changeover switch 17 switches the control error RA to the second PI controller 13. In other words, the control error RA is fed as an input variable to the second PI controller 13 which enables the second valve control signal VS′ for actuating the overload valve 8.

On the other hand, if the actuating signal AS of logical value 1 is not present but the actuating signal AS of 0 is present, the second PI controller 13 ensures that the second PI controller 13 does not generate a signal to open the overload valve 8. Is supplied with a predetermined reference value RW which is selected to ensure that In the exemplary embodiment, the reference value RW has a magnitude corresponding to an excessive frequency increase of 5%, ie a grid frequency NF 5% higher than the frequency target value.

During operation, the control error RA determined from the output actual value LI and the output target value LS and the value WE is supplied to the first PI controller 12, then the second valve control signal VS′ is supplied to the live steam valve 7. It The open degree OG is detected, the open state ZU is determined by the second comparator 15, and is supplied to the AND element 10.

If the frequency reduction FA is further detected using the first comparator 14, the AND element 10 provides the actuation signal AS, in response to which the control error RA then overloads the first valve control signal VS. It is connected to a first PI controller 12 which feeds the valve 8. On the other hand, when the frequency reduction FA is not present, the overload valve 8 is kept closed. In other words, the overload valve 8 is opened only when it is simultaneously detected that the frequency reduction FA and the live steam valve 7 are completely opened.

Therefore, efficiency during rated operation can be increased, and the turbine output can be dynamically increased by using the overload valve 8 in case of frequency drop.

While the present invention has been illustrated and described in detail by the preferred exemplary embodiments, the invention is not limited by the disclosed examples, and those skilled in the art can use them without departing from the scope of protection of the invention. Other variants can be derived from.

1 turbine generator
2 generator
3 turbine
4 high pressure stage
5 Medium pressure stage
6 Low pressure stage
7 Live steam valve
8 Overload valve
9 devices
10 AND element
11 Characteristic curve element
12 First PI controller
13 Second PI controller
14 First comparator
15 Second comparator
16 subtractor elements
17 Changeover switch
AS operation signal
FA frequency drop
GW limit value
LI output actual value
LS output target value
NF grid frequency, network frequency
OG openness
RA control error
RW reference value
SW threshold
VS 1st valve control signal
VS' Second valve control signal
WE value
ZU open state

Claims (13)

A method of operating a turbine generator (1) having a turbine (3) and a generator (2) connected to the turbine (3), the generator (2) comprising a three-phase current or a three-phase alternating current. The current is designed to be fed into the grid at a grid frequency (NF), the turbine having a live steam valve (7) and an overload valve (8), the method comprising:
Monitoring the grid frequency (NF) for frequency reduction (FA) with respect to a frequency target,
Detecting the state of the live steam valve (7) with respect to the open state (ZU);
Opening the overload valve (8) in response to detecting a frequency drop (FA) and in response to a detected open state (ZU) of the live steam valve (7),
The overload valve (8) is opened only when it is simultaneously detected that the frequency reduction (FA) and the live steam valve (7) are completely opened,
An indicator binary signal is generated in response to detecting a frequency drop (FA) and a further indicator binary signal is generated in response to detecting the open state (ZU) of the live steam valve (7). The method wherein the two indicator signals are combined with an AND element (10) to generate an actuation signal (AS) for opening the overload valve (8) . At least one output target value (LS) is compared with an actual output value (LI) to determine a control error (RA), and the overload valve (8) is set to the determined control error (RA). The method of claim 1 , wherein the method is opened accordingly. At least one output target value (LS) is compared with an actual output value (LI) to determine a control error (RA), and the live steam valve (7) is set to the determined control error (RA). Method according to any one of claims 1 to 2 , which is opened accordingly. Method according to any one of claims 1 to 3 , wherein the grid frequency (NF) is compared with the frequency target value in order to infer the presence of a frequency drop (FA). A value (WE) indicating a frequency reduction (FA) is determined by evaluating at least the grid frequency (NF) and the frequency target value, and when the value (WE) is greater than a limit value (GW), 5. The method according to any one of claims 1 to 4 , wherein a frequency reduction (FA) is inferred. Live steam sensor signal (FS) is compared with a threshold value (SW), if the live steam sensor signal (FS) is greater than the threshold value (SW), the open state (ZU) is deduced from claim 1 5 The method according to any one of 1. A computer program product having software components for implementing the method according to any one of claims 1-6 . A device (9) for controlling the turbine (3) of a turbine generator (1) having a turbine (3) and a generator (2) connected to the turbine (3), the generator (2) ) Is designed to supply a three-phase current or a three-phase alternating current into the grid at a grid frequency (NF), said turbine (3) comprising a live steam valve (7) and an overload valve (7). 8) and the device (9) monitors the grid frequency (NF) for frequency reduction (FA) with respect to a frequency target to determine the open state (ZU) of the live steam valve (7). Designed to open the overload valve (8) in response to detecting the frequency drop (FA) and in response to a detected open state (ZU) of the live steam valve (7), The overload valve (8) is opened only when it is simultaneously detected that the frequency reduction (FA) and the live steam valve (7) are completely opened,
The device (9) is designed to generate an indicator binary signal and in response to detecting an open state (ZU) of the live steam valve (7), to generate a further indicator binary signal, The device (9) has an AND element (10) that logically combines the two signals so that the device (9) generates an actuation signal (AS) that opens the overload valve (8). Device that is designed for. The device (9) is responsive to the actuation signal (AS) to compare at least one output target value (LS) with an actual output value (LI) to determine a control error (RA), 9. A device (9) according to claim 8 designed to open the overload valve (8) in response to a determination (FA) of the control error (RA) in response to a reduction (FA). The device (9) compares an output target value (LS) with an actual output value (LI) to determine a control error (RA), and the live steam is determined according to the determined control error (RA). Device (9) according to any one of claims 8 to 9 , designed to open the valve (7). 11. The device (9) according to any of claims 8 to 10 , wherein the device (9) is designed to compare the grid frequency (NF) with the frequency target in order to infer the presence of a frequency drop (FA). Device (9) according to paragraph 1. The device (9) determines a value (WE) indicating a frequency decrease (FA) by evaluating at least the power grid frequency (NF) and the frequency target value, and the value (WE) is a limit value. Device (9) according to any one of claims 8 to 11 , designed to infer a frequency drop (FA) when greater than (GW). The device (9) compares the raw steam sensor signal (FS) with a threshold value (SW) and infers the open state (ZU) if the raw steam sensor signal (FS) is greater than the threshold value (SW). Device (9) according to any one of claims 8 to 12 , which is designed to

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