JPH07119408A - Emergency controller for steam turbine - Google Patents

Abstract

PURPOSE:To prevent a steam turbine from overspeed tripping and low frequency tripping by detecting the whole output of turbine exactly according to an operating condition. CONSTITUTION:In a device which suddenly closes regulating valves 5, 6 for steam supplied to steam turbine 1, 2 if some deviation which exceeds a prescribed value occurs between the output of the steam turbines 1, 2 and the load of a generator 3, the respective pressure after the first stage of each of the high pressure turbine 1 and the low pressure turbine 2 connected to the turbine 1 is detected by pressure transmitters 21, 22 to multiply the pressure after the first stage of the respective turbines by coefficients K1, K2 corresponding to the load sharing ratio of the respective turbines with multipliers 26, 27 and add the obtained value with an adder. Utilizing the added value as the output of the steam turbine, a deviation to the load of the generator 3 is determined through a load current measured by a current relay 11 (or current transmitter).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is applied to steam turbine power generation equipment, and when a deviation exceeding a predetermined value occurs between the output of the steam turbine and the load of the generator,
The present invention relates to an emergency control device for a steam turbine for rapidly closing a control valve for steam supplied to the steam turbine.

[0002]

2. Description of the Related Art In a power generation facility using a steam turbine having bleed air or mixed air, when a deviation exceeding a predetermined value occurs between the output of the steam turbine and the load of the generator, the steam supplied to the turbine is controlled. A device is provided to close the valve rapidly to prevent turbine overspeed. FIG. 3 shows a system diagram of this type of device provided in a conventional steam turbine power generation facility.

In FIG. 3, the steam turbine power generation facility is
The high pressure turbine 1 and the low pressure turbine 2 are used as drive sources to drive the generator 3 to obtain electric power.
Is supplied with main steam from a boiler (not shown) via the main steam stop valve 4 and the main steam control valve 5. Then, a part of the steam that has worked in the high-pressure turbine 1 is sent to the factory as bleed air, and the rest is evacuated to the low-pressure turbine 2 via the bleed air control valve 6.
Sent to. Further, the steam that has worked in the low-pressure turbine 2 is sent to a condenser (not shown) (or to a factory).

By the way, there may be a deviation between the output on the turbine side and the load on the generator side due to a failure on the system side. In such a case, the supply of steam to the turbine is restricted. Prevents the turbine from overspeeding. A device therefor will be called an emergency control device.

In this conventional emergency control device, an electromagnetic valve 9 provided in a hydraulic system connected to the oil cylinders 7 and 8 of the main steam control valve 5 and the extraction control valve 6 and the outputs of the turbines 1 and 2 are provided. The pressure switch 10 that detects the pressure after the first stage of the high-pressure turbine 1 and outputs an ON signal when the pressure after the first stage of the high-pressure turbine 1 exceeds a certain value α, and the load that detects the load on the generator 3 side From the current relay 11 that outputs an ON signal when the current becomes a certain value β or less, and the calculator 12 that supplies an operation signal to the solenoid valve 9 when both signals from the pressure switch 10 and the current relay 11 are ON. Made of

Therefore, if the high-pressure turbine 1 is operating normally, an ON signal is output from the pressure switch 10 by the calculator 12.
If the load of the generator 3 is reduced and the current is below a certain value at this time, the current relay 11
Since the ON signal is output from the calculator 1 to the calculator 12,
An operation signal is output from 2, and the solenoid valve 9 is operated by this.

That is, the solenoid valve 9 is a three-way valve and normally supplies the hydraulic pressure from the hydraulic system to the oil cylinders 7 and 8. However, when an operation signal is received from the computing unit 12, the valve on the hydraulic system side. Closes and opens the valve to the drain side. Therefore, the oil in the oil cylinders 7 and 8 of the main steam control valve 5 and the extraction control valve 6 is discharged to the drain, and the main steam control valve 5 and the extraction control valve 6 are rapidly closed, and the high pressure turbine 1 and the low pressure turbine 1 By limiting the supply of steam to the turbine 2, overspeed of the turbine is prevented.

[0008]

By the way, in the conventional emergency control apparatus described above, the pressure switch 10 detects the output of the high pressure turbine 1 after the first stage and uses it as the output of the steam turbine. However, since the low-pressure turbine 2 is connected to the high-pressure turbine 1, the output of the entire turbine is not necessarily detected accurately depending on the output state of the low-pressure turbine 2, that is, the extraction amount state. There was a problem.

That is, the setting of the post-stage pressure of the first stage of the high-pressure turbine 1 is performed under the condition of the normal operation base. Therefore, when the extraction amount is set to be different from that of the normal operation base, the first stage of the high-pressure turbine 1 is set. There will be a difference between the estimated output on a post pressure basis and the actual output of the overall turbine. Therefore, since the relationship between the output of the pressure switch 10 supplied to the calculator 12 and the output from the current relay 11 is broken, which is expected in design, the calculator is operated when a large load deviation is required to operate the solenoid valve 9. When the main steam control valve 5 and the extraction control valve 6 cannot be closed rapidly without the operation signal from 12 being output, or conversely, when there is a small load deviation in which the solenoid valve 9 should not be operated, calculation is performed. There was a problem that an operation signal was output from the device 12 and the main steam control valve 5 and the extraction control valve 6 were suddenly closed.

When there is a large deviation between the output on the turbine side and the load on the generator side, if the main steam control valve 5 and the extraction control valve 6 cannot be closed rapidly, the turbine will cause an overspeed trip. In addition, if the main steam control valve 5 and the extraction control valve 6 are suddenly closed when the load deviation is small, the rotational speed of the turbine is too low and a low frequency trip occurs. These phenomena have been problematic in that they hinder the rapid response of the turbine power generation equipment in the event of a system failure, or hinder normal power supply to the system.

The present invention has been made to solve the problems of the prior art as described above, and accurately detects the output of the entire steam turbine in accordance with the operating state to prevent overspeed trip and low frequency trip of the turbine. An object is to provide an emergency control device for a steam turbine that can be prevented.

[0012]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention supplies a steam turbine with a deviation exceeding a predetermined value between the output of the steam turbine and the load of the generator. In an emergency control device for a steam turbine that rapidly closes a control valve for steam, the pressure transmitters that detect the pressures of the high-pressure turbine and the low-pressure turbines connected to the high-pressure turbine after the first stage, and the pressure transmitters that detect the pressures. It has a multiplier for multiplying the first stage post-pressure of the turbine by a coefficient corresponding to the load sharing factor of each turbine, and an adder for adding the values obtained by each multiplier, and the output of this adder is steamed. The deviation between the output of the turbine and the load of the generator is obtained through the load current.

[0013]

[Operation] According to the above means, the pressure after the first stage of each of the high-pressure turbine and the low-pressure turbine connected to the high-pressure turbine is detected by the pressure transmitter, and the load distribution of each turbine is shared by the pressure after the first stage of each turbine. Multiply the coefficient corresponding to the rate with a multiplier, add the obtained values with an adder, and use the addition result as the output of the steam turbine to determine the deviation from the load of the generator via the load current. As a result, the output of the entire turbine can always be detected accurately according to the operating conditions, and when a load cutoff phenomenon occurs due to a system accident, load cutoff detection and turbine overspeed prevention functions work properly and stabilize. Power can be supplied.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of an emergency control device for a steam turbine according to the present invention will be described in detail below with reference to FIGS. In these figures, the same parts as those in FIG. 3 are designated by the same reference numerals and the description thereof will be omitted.

FIG. 1 shows an embodiment in which the present invention is applied to a one-stage extraction / condensation turbine power generation facility. That is, the main steam supplied from the boiler (not shown) works in the high-pressure turbine 1 and the low-pressure turbine 2. Therefore,
The output of the entire turbine is the sum of the outputs of the high pressure turbine 1 and the low pressure turbine 2. By the way, the output of the turbine is almost proportional to the flow rate of steam flowing through the turbine, and
Since the post-stage pressure is also proportional to the flow rate of steam,
The post-stage pressure is an index of turbine output.

Therefore, in order to detect the first-stage post-pressure of the high-pressure turbine 1 and the first-stage post-pressure of the low-pressure turbine 2 separately, the high-pressure turbine 1 has a first pressure transmitter 2
1 and also the low pressure turbine 2 is provided with a second pressure transmitter 22. Then, the first-stage post-pressure signals of the high-pressure turbine 1 and the low-pressure turbine 2 from the pressure transmitters 21 and 22 are sent to the load cutoff detection calculation circuit 23.

The load cutoff detection arithmetic circuit 23 is provided with coefficient generators 24 and 25 and multipliers 26 and 27. The coefficient generators 24 and 25 generate a coefficient corresponding to the load sharing rate of the high-pressure turbine 1 and the low-pressure turbine 2, and the coefficient generator 24 outputs a coefficient K ₁ corresponding to the load sharing rate of the high-pressure turbine _1. Is preset from the coefficient generator 25 so as to generate a coefficient K ₂ corresponding to the load sharing ratio of the low-pressure turbine 2.

Therefore, one multiplier 26 multiplies the output from the first pressure transmitter 21 by the coefficient K ₁ from the coefficient generator 24, and the other multiplier 27 produces the second value.
The output from the pressure transmitter 22 of the
The coefficient K ₂ from 5 is multiplied. And each multiplier 2
The outputs of 6 and 27 are added by the adder 28. Therefore,
The result of addition by the adder 28 becomes a signal 29 indicating the output of the entire turbine obtained by adding the respective outputs of the high pressure turbine 1 and the low pressure turbine 2. The output signal 29 from the adder 28 has a predetermined value α (for example, α = 80%).
Output) and above, it is sent to the switch circuit 30 which is set to output an ON signal.

On the other hand, on the generator 3 side, when the load current of the generator 3 falls below a certain value β (eg β = 20% load),
A current relay 11 set to output an ON signal is provided, and a signal from the current relay 11 is sent to the load cutoff detection calculation circuit 23. That is, the load cutoff detection arithmetic circuit 23 is provided with an arithmetic unit 31,
When the signal from the current relay 11 and the signal from the above-mentioned switch circuit 30 are supplied and both the signals from the current relay 11 and the switch circuit 30 are ON, the main steam control valve 5 and the extraction control valve 6 are turned on. An operation signal for causing the quick closing operation is supplied from the calculator 31 to the solenoid valve 9.

Next, the operation will be described. When the steam turbine is normally operated at, for example, 100% load, the output signal 29 on the turbine side has a value substantially equivalent to 1 (or 100%), and this value is equal to or greater than the set value α of the switch circuit 30. An ON signal is output from the switch circuit 30 and supplied to the arithmetic unit 31. Similarly, since the load on the generator 3 side is balanced with the turbine output, the load current is β or more, so that the ON signal is not output from the current relay 11 and the OFF signal is supplied to the calculator 31. There is. Therefore, the operation signal is not output from the computing unit 31, and the solenoid valve 9 acts to supply the oil pressure from the hydraulic system to the oil cylinders 7 and 8 to operate the main steam control valve 5 and the extraction control valve 6. Since it opens, steam is supplied to each turbine 1 and 2 and operates normally.

By the way, when an accident occurs on the system side and the load suddenly changes, the load current on the generator 3 side decreases. Therefore, when the value falls below the set value β, the current relay 11 turns ON.
The signal is output to the calculator 31. At this time, the output signal 29 on the turbine side is normal, and the switch circuit 30 turns on.
Since the signal is supplied to the computing unit 31, both the inputs to the computing unit 31 become ON signals, and the operating conditions are satisfied, so that the operating signal is output from the computing unit 31 to the solenoid valve 9.
This operation signal causes the solenoid valve 9 to operate, closing the valve to the hydraulic system side and opening the valve to the drain side. Therefore, the oil in the oil cylinders 7 and 8 of the main steam control valve 5 and the extraction control valve 6, respectively, is discharged to the drain, the main steam control valve 5 and the extraction control valve 6 are rapidly closed, and the high pressure turbine 1 and the low pressure turbine Blocking the inflow of steam into 2 prevents turbine overspeed.

Next, a second embodiment of the present invention will be described with reference to FIG. In FIG. 2, the same parts as those in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. In this embodiment, the current transmitter 32 is used in place of the current relay 11 in FIG. 1, so that the configuration of the load cutoff detection calculation circuit 23 in FIG. 1 is shown as the load cutoff detection calculation circuit 33. It's a little different.

That is, for detecting the load of the generator 3,
A current transmitter 32 is provided in place of the current relay 11, which measures the load current of the generator 3 and supplies the signal to the load cutoff detection arithmetic circuit 33. As in the first embodiment, the load cutoff detection arithmetic circuit 33 includes coefficient generators 24 and 25, multipliers 26 and 27, and an adder 28.
And a first turbine of the turbine from the adder 28.
A signal 29 is obtained which represents the output of the entire turbine calculated on the post-stage pressure basis.

Therefore, the signal 2 indicating the output of the entire turbine
9 and the current signal of the generator 3 from the current transmitter 32 are compared by a comparator 34 to obtain a load deviation signal 35,
This signal 35 is supplied to the switch circuit 36. The load deviation signal 35 is zero during the normal operation of the steam turbine power generation equipment, and a deviation occurs when the load is cut off due to a system accident or the like. When the deviation signal 35 exceeds a certain value γ (for example, γ = 60%), the switch circuit 3
An ON signal is sent from 6 to the solenoid valve 9. The operation of the solenoid valve 9 is similar to that of the first embodiment, and the same effects as those of the first embodiment can be obtained.

Although the present invention has been described using the one-stage extraction / condensation turbine, the present invention can be applied to the case where there are a large number of extraction stages, such as two-stage and three-stage, and the mixed-air turbine. Needless to say. Further, in the case of the back pressure turbine, the steam leaving the low pressure turbine is sent to the factory in the same manner as the extraction air.

[0026]

As described in detail above, according to the present invention,
Since the output of the entire turbine is obtained by detecting the pressure after the first stage of each of the high-pressure turbine and the low-pressure turbine connected to the high-pressure turbine, the output of the entire turbine can be accurately detected in any operating condition. for that reason,
Responding appropriately to a load shedding phenomenon caused by a system accident, etc., it is possible to prevent the unit from tripping due to this phenomenon and to reliably prevent turbine overspeed. An emergency controller for a steam turbine is provided.

[Brief description of drawings]

FIG. 1 is a system diagram showing an embodiment of a steam turbine emergency control device according to the present invention.

FIG. 2 is a system diagram showing another embodiment of an emergency control device for a steam turbine according to the present invention.

FIG. 3 is a system diagram showing a conventional emergency control device for a steam turbine.

[Explanation of Codes] 1 high-pressure turbine 2 low-pressure turbine 3 generator 5 main steam control valve 6 extraction control valve 9 solenoid valve 11 current relay 21, 22 pressure transmitter 23 load cutoff detection arithmetic circuit 24, 25 coefficient generator 26, 27 multiplication 28 adder 30 switch circuit 31 calculator 32 current transmitter 33 load cutoff detection calculator 34 comparator 36 switch circuit

Claims (3)

[Claims] 1. An emergency control device for a steam turbine, wherein a control valve for steam supplied to a steam turbine is rapidly closed when a deviation exceeding a predetermined value occurs between the output of the steam turbine and the load of the generator. , A pressure transmitter that detects the pressure after the first stage of each of the high-pressure turbine and the low-pressure turbine connected to the high-pressure turbine, and the pressure after the first stage of each turbine detected by these pressure transmitters corresponds to the load sharing ratio of each turbine. It has a multiplier that multiplies a coefficient and an adder that adds the values obtained by the respective multipliers, and the output of this adder is used as the output of the steam turbine to calculate the deviation between the load of the generator and the load. An emergency control device for a steam turbine, characterized in that the control is performed via electric current. 2. An emergency control device for a steam turbine, wherein a control valve for steam supplied to the steam turbine is rapidly closed when a deviation exceeding a predetermined value occurs between the output of the steam turbine and the load of the generator. , A pressure transmitter that detects the pressure after the first stage of each of the high-pressure turbine and the low-pressure turbine connected to the high-pressure turbine, and the pressure after the first stage of each turbine detected by these pressure transmitters corresponds to the load sharing ratio of each turbine. A multiplier that multiplies a coefficient, an adder that adds the values obtained by the multipliers, a switch circuit that generates a predetermined signal when the output of the adder is a predetermined value or more, and a load current of the generator. And a current relay that generates a predetermined signal when the measured value is equal to or less than a predetermined value, and a predetermined signal is obtained from both the switch circuit and the current relay. Emergency control of a steam turbine, characterized in that the that suddenly closes the control valve of the steam supplied to the steam turbine when the. 3. A steam turbine emergency control device for rapidly closing a control valve for steam supplied to a steam turbine when a deviation exceeding a predetermined value occurs between the output of the steam turbine and the load of the generator. , A pressure transmitter that detects the pressure after the first stage of each of the high-pressure turbine and the low-pressure turbine connected to the high-pressure turbine, and a multiplier that multiplies the output of each pressure transmitter by a coefficient corresponding to the load sharing ratio of each turbine,
An adder for adding the values obtained by the respective multipliers, a current transmitter for measuring the load current of the generator,
A comparator that obtains a load deviation signal by comparing the outputs of the adder and the current transmitter, and a steam control valve for supplying steam to the steam turbine when the load deviation signal exceeds a predetermined value. An emergency control device for a steam turbine, which is characterized in that it is closed rapidly.