JP2001164906A - Turbine protection test device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To support operation of the master trip solenoid valve of a turbine emergency trip device and a soundness confirming test of a control logic, in a plant under operation. SOLUTION: In generating equipment formed such that a turbine trip valve to stop rotation of the turbine of a generating plant is controlled by a turbine emergency trip device provided with mater trip solenoid valves A and B, a central control panel 27 is provided with a test controlling and monitoring device 29 having a master trip solenoid logic test panel 28 and a control logic. During a test of the aster trip solenoid valve A, a turbine trip simulated signal of an actual turbine stop command is generated by the test button 35a of a trip channel A. At the same time when the solenoid valve A is operated by a simulated signal, a turbine trip valve is brought into a non-operation state under the condition that the solenoid valve A is under a test, the solenoid valve A is tested without stopping a turbine. The same may be said of the master trip solenoid valve B.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a turbine protection test apparatus applicable to a test of a turbine emergency device of a power plant.

[0002]

2. Description of the Related Art Conventionally, a technique for testing a turbine emergency device includes a device for confirming only the operation of a master trip solenoid valve and its logic, as disclosed in JP-A-7-145705. Things. Normally, the master trip solenoid valve of the turbine emergency device operates when the normally excited state is de-energized by the signal of the turbine trip determination logic including various factors, the high-pressure oil is discharged, the turbine speed control valve and When the main stop valve closes, the turbine trips (stops).

[0003]

However, in the conventional technique as described above, since the test is to confirm only the operation of the master trip solenoid valve, the logic on the upstream side that generates the actual turbine trip signal is abnormal. Occurs, and if the logic circuit cannot output the turbine trip signal, the abnormality cannot be detected.

SUMMARY OF THE INVENTION In view of the above circumstances, it is an object of the present invention to support a test for confirming the operation of a master trip solenoid valve and the integrity of control logic.

[0005]

Means for Solving the Problems To solve the above problems, a plurality of solenoid valves for controlling a turbine trip valve for stopping the rotation of a turbine of a power generation plant. A turbine trip simulation signal of an actual turbine stop command is generated, and a specific solenoid valve is operated using the simulation signal.At the same time, the turbine trip valve is disabled under the condition that the specific solenoid valve is under test. Test a particular solenoid valve without shutting down the turbine. Here, the turbine trip simulation signal and the actual turbine stop command are input to the OR logic, and the turbine trip valve is disabled by the AND logic output of the OR logic output and the negative logic signal during the test of the specific solenoid valve. Also,
When an AND signal of the trip position signal of the specific solenoid valve and the NOT logic signal of the simulation signal is input to the OR logic of the operation signals of the other solenoid valves among the plurality, and when the specific solenoid valve is at the trip position, Consider the test state and deactivate other solenoid valves. Also, during testing of a particular solenoid valve of the plurality,
When an actual turbine stop command is issued, the operation signal of the other solenoid valve of the plurality is output, and at the same time, the operation signal of the turbine trip valve is generated on condition that the other solenoid valves are not being tested. A specific solenoid valve and another solenoid valve are simultaneously operated by respective operation signals, and the turbine trips.

[0006]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 4 shows a basic system configuration of a thermal power plant to which the present invention is applied. The basic configuration of a thermal power plant is to generate steam by burning fuel such as heavy oil and coal and heating water in a steam generator 1, and using the steam to generate high-pressure turbine 2, medium-pressure turbine 3, low-pressure The turbine 4 rotates to generate electricity from the generator 14. The steam generated from the steam generator 1 is first sent to the high-pressure turbine 2 and rotates the high-pressure turbine 2. Then the steam is reheated again 11
After being reheated, it is sent to the intermediate pressure turbine 3, rotates the intermediate pressure turbine 3, and then is sent to the low pressure turbine 4, rotates the low pressure turbine 4, enters the condenser 5, and condenses water. become. The condensed water is pressurized by a condensate pump 6 and exchanges heat with extracted steam (not shown) extracted from the middle of the turbine in a low-pressure feed water heater 7 to be heated. The condensed water whose temperature has been raised passes through the deaerator 8 to remove impurities such as oxygen contained in the condensed water, and is supplied as water. This water supply is pressurized by a water supply pump 9 and exchanges heat with bleed steam (not shown) extracted from the middle of the turbine in a high-pressure water heater 10 to be heated to enter the steam generator 1 again. become. At this time, the steam fed into the high-pressure turbine 2 is adjusted by the control valve 12, and the turbine speed is controlled. Also, if an abnormality occurs in the plant,
When the turbine is urgently stopped, control for closing the steam stop valve 12a and the reheat steam stop valve 13 (turbine trip valve) immediately is performed.

When a plant abnormality occurs, the steam stop valve 12
There is a turbine emergency trip device as a device for immediately closing the a and the reheat steam stop valve 13 and stopping the rotation of the turbine. FIG. 5 shows the configuration. The turbine emergency trip device is constituted by a servo valve including a mechanical trip valve 17, a lockout valve 18, and a master trip servo valve 19. Each valve is supplied by supplying high-pressure oil to the steam stop valve 12a and the reheat steam stop valve 13. At the same time, the high-pressure oil is discharged as a drain in the event of an abnormality, and the steam stop valve 12a and the reheat steam stop valve 1 are maintained.
3 has a function to quickly close. This high-pressure oil state is maintained by the supply oil from the hydraulic unit 20, and the pressure is monitored by the hydraulic pressure monitoring instrument 21. First, the mechanical trip signal generating unit 15 monitors the number of rotations of the turbine, and when the number of rotations exceeds a predetermined value, generates a mechanical trip signal 16, the mechanical trip valve 17 is operated, and the high pressure oil is mechanically tripped. By discharging as the valve drain 22a, the steam stop valve 12a and the reheat steam stop valve 13 are rapidly closed. Here, the mechanical trip signal generating unit 15 operates the mechanical trip valve 17 also by the manual mechanical trip signal 16 by the operator, discharges the high pressure oil as the drain 22a, and operates the steam stop valve 12a and the reheat steam stop valve 13. Can be quickly closed. The lockout valve 18 is a mechanical trip valve 1
7 is used to supply high-pressure oil only to the master trip servo valve 19 in order to maintain the high pressure state of the oil supplied to the steam stop valve 12a and the reheat steam stop valve 13 when performing the operation test of FIG. . That is, before the operation test of the mechanical trip valve 17 is started, the lockout valve 18 is set to the test position, and the mechanical trip valve 17 is operated by the operation of the oil trip solenoid valve (not shown) thereafter. 17 can be confirmed. On the other hand, during this test, the high-pressure oil is discharged from the mechanical trip valve 17 as the drain 22a, but the high-pressure oil supplied from the lockout valve 18 to the master trip servo valve 19 is not discharged as the master trip servo valve drain 22b. The high pressure is maintained and the turbine does not trip.

Next, the operation of the master trip servo valve 19 will be described. 6 and 7 show four operating states of the master trip solenoid valves 25a and 25b for controlling the high pressure oil state of the master trip servo valve 19. During normal operation of the plant, high pressure oil needs to be supplied to the steam stop valve 12a and the reheat steam stop valve 13, so that the high pressure oil inflow line 23 to the master trip servo valve 19, the steam stop valve 12a and the reheat The high pressure oil supply line 24 to the steam stop valve 13 needs to maintain a high pressure state. Accordingly, the master trip solenoid valve A (MTSV-A) 25a and the master trip solenoid valve B (MTSV-B) 25b are in the excited state shown in FIG. 6A, and the high-pressure oil inflow line 23 and the high-pressure oil supply line From 24, high-pressure oil is supplied to the steam stop valve 12a and the reheat steam stop valve 13. When a turbine trip signal is generated, that is, the master trip solenoid valve A (MTSV-A) 25a and the master trip solenoid valve B
(MTSV-B) 25b is in a non-excited state,
Since the state shown in (b) is reached, the high-pressure oil is discharged as the drain 22b. For this reason, the oil pressure supplied to the steam stop valve 12a and the reheat steam stop valve 13 decreases, and the steam stop valve 1
2a and the reheat steam stop valve 13 are suddenly closed, causing a turbine trip. During the operation of the plant, it is necessary to confirm the soundness of the master trip solenoid valve A (MTSV-A) 25a and the master trip solenoid valve B (MTSV-B) 25b. I have. The turbine trip is a master trip solenoid valve A
(MTSV-A) 25a and master trip solenoid valve B
(MTSV-B) The master trip solenoid valve A (MTSV-B) 25b is generated only when both magnets are not excited.
VA) 25a and master trip solenoid valve B (MTSV
-B) As an operation test method of 25b, the master trip solenoid valve A (MTSV-A) 25a and the master trip solenoid valve B (MTSV-B) 25b are each de-energized, and the operation is confirmed. That is, when the master trip solenoid valve A (MTSV-A) 25a is tested,
As shown in FIG. 7C, the master trip solenoid valve A (MT
Only the SV-A) 25a is operated, and the operation is confirmed by the operation confirmation switch 26a. In this case, FIG.
As shown in (c), the drain 22b is not discharged, and high-pressure oil is secured in the high-pressure oil inflow line 23 and the high-pressure oil supply line 24, so that a turbine trip does not occur. Similarly, when the master trip solenoid valve B (MTSV-B) 25b is tested, only the master trip solenoid valve B (MTSV-B) 25b is operated as shown in FIG. Confirm at 26b. In this case, as shown in FIG. 7D, the drain 22b is not discharged and the high-pressure oil is supplied to the high-pressure oil inflow line 23 and the high-pressure oil supply line 24, so that a turbine trip does not occur.

FIG. 1 shows a system configuration of a turbine protection test apparatus according to an embodiment of the present invention. In the present embodiment, a turbine emergency trip device of a thermal power plant will be described by taking an operation from a central control room as an example. The master trip solenoid valve test of the turbine emergency trip device of this embodiment is performed by operation from the central control panel 27 in the central control room. A master trip solenoid valve logic test panel 28 is provided for interfacing with the operator, where the operator performs the test. The test signal from the master trip solenoid valve logic test panel 28 is sent to the master trip solenoid valve test control and monitoring device 29, and the test signal is sent to the turbine emergency trip device 30 according to the control logic contained therein. This turbine emergency trip device 30 is the device described in FIG. 5 described above. The operation status signals of the master trip solenoid valves 25a and 25b are input to the master trip solenoid valve test control / monitoring device 29, and the test status is displayed on the master trip solenoid valve logic test panel 28. The master trip solenoid valve logic test panel 28 includes a trip channel (A) test permission lamp 31a, a trip channel (B) test permission lamp 31b, a trip channel (A) testing lamp 32a, a trip channel (B) testing lamp 32b, Master trip solenoid valve (A) operation confirmation lamp 33a, master trip solenoid valve (B) operation confirmation lamp 33b, trip channel (A) test confirmation button 3
4a, Trip channel (B) test confirmation button 34
b, Trip channel (A) test start button 35
a, Trip channel (B) test start button 35b
Having.

Next, master trip solenoid valve test control
The control logic of the monitoring device 29 will be described with reference to FIGS. 2 and 3 together with the operation of the master trip solenoid valve logic test panel 28. The master trip solenoid valve A (25
Since a) and B (25b) have the same operation and logic,
The operation of the master trip solenoid valve A (25a) is described below.
The explanation is based on logic. Before starting the test,
The operator confirms that the test permission lamps 31a and 31b are illuminated by the master trip solenoid valve logic test panel 28.
Confirm with. Next, the trip channel (A) test confirmation button 34a is pressed. As shown in FIG. 2, when this button 34a is pressed and the trip channel (B) test confirmation button 34b is not pressed, the channel (A) test start (middle) lamp 32a is turned on. The test start signal 44a of the channel (A) test start (medium) lamp 32a is provided by a timer 42 to prevent erroneous lighting.
a is set and the logic is turned on only when the signal output continues for a specified time during a reliable operation of the operator. afterwards,
By pressing the channel (A) test button 35a, a turbine trip simulation signal 43a is generated. This signal is also provided with a timer 42b for preventing occurrence of an erroneous signal,
Only when the turbine trip simulation signal 43a continues for a specified time, the turbine trip simulation signal 43a is output. The turbine trip simulation signal 43a is input to the OR logic of the turbine trip signal (A) 36a and the turbine trip signal (B) 36b, and the output is output as a turbine trip logic signal 39a. The turbine trip logic signal 39a is generated by a turbine trip signal (A) 36a during normal operation and outputs a channel (A) mechanical trip valve operation signal 38a. At the time of a channel (A) test, a channel (A) test start signal is output. Since the turbine trip logic signal 39a is output because the 44a is in the ON (1) state, the mechanical trip valve operation signal which is an AND logic output of this signal and the NOT logic 41 signal of the channel (A) test start signal 44a. 38a is not output and the turbine trip (steam stop valve 1
2a and trip of the reheat steam stop valve 13). The master trip solenoid valve (A) operation signal 39a is
As shown in FIG. 3, the signal passes through the NOT logic 41 and becomes the master trip solenoid valve (A) operation signal 40a. Normally, the master trip solenoid valve (A) operation signal 39a is OFF.
(0), the output of the NOT logic 41 is ON (1), and when the master trip solenoid valve (A) operation signal 39a is ON (1), the master trip solenoid valve (A) The operation signal 40a becomes OFF (0), and the master trip solenoid valve operates (non-excitation). Also, the channel (A) test permission lamp 31a has the master trip solenoid valve (A) operation signal 39a ON (1), that is, the master trip solenoid valve (A) operation signal 40a is O
When the signal becomes FF (0), and when the master trip solenoid valve (A) trip position signal 37a is in the ON (1) state, the signal after the negative logic 41 is OFF (0), so the light is turned off. Notify the operator that the channel (A) test cannot be performed. According to the above test, when the master trip solenoid valve (A) operates, the master trip solenoid valve (A) trip position signal 37a is turned on.
(1), whereby the master trip solenoid valve (A) test operation signal 45a in FIG. 2 is turned ON (1), the valve operation display 33a is turned on, and the operator can control the control trip and the master trip solenoid valve (A). Normal operation can be confirmed. This is the channel (A) test button 35a
Even if is pressed, during the test of the solenoid master trip solenoid valve (A), the logic does not cause a turbine trip.

On the other hand, the master trip solenoid valve (A) trip position signal 37a is shown in FIG.
The AND signal 46a with the negative logic 41 signal of 9a is input to the OR logic of the master trip solenoid valve (B) operation signal 40b. At this time, the operation signal 40b is turned ON (1), and the master trip solenoid valve (B) is operated (non-excitation).
Do not let. This is a safety circuit for preventing the master trip solenoid valve (B) from erroneously operating when the master trip solenoid valve (A) operates and not causing a turbine trip. That is, if the channel (A) test is performed, the channel (A) test state is reset when the master trip solenoid valve (A) is in the trip position and the trip position signal 37a is output, and the turbine trip signal is reset. Channel (B) continuously after 39a is turned off
A test was performed to prevent the master trip solenoid valve (B) from operating. In other words, when the master trip solenoid valve (A) is in the trip position even though the turbine trip signal (A) is not output, it is regarded as a test state, and the logic of the master trip solenoid valve (B) does not operate. Ensure the safety of turbine trip malfunction during testing.

Further, during the channel (A) test, an actual turbine stop signal is generated, and the turbine trip signal (A) 36a or the turbine trip signal (B) 36b
Occurs, a master trip solenoid valve (B) operation signal 39b is output. In this case, channel (B)
Since the test has not been selected, the channel (B) test start signal 44b is OFF (0), and therefore, the channel (B) mechanical trip valve operation signal 3
8b occurs. Master trip solenoid valve (A)
The operation signal 40a and the master trip solenoid valve (B) are also turned off (0), the master trip solenoid valves (A) / (B) are simultaneously de-energized (operation), and the mechanical trip valve 17 operates (drain discharge). ) And a turbine trip occurs. Thereby, the channel (A)
Even during the test, when an actual turbine stop signal is generated, the turbine is tripped by the turbine trip signal (A) 36a or the turbine trip signal (B) 36b, and safety is ensured. The above control is the same for the test of the channel (B).

The above description is a test apparatus for the logic of the operation of the master trip solenoid valve by a two-channel signal.
If only the logic related to the channel test (A) or (B) and the switch and display of the test panel are applied, 1
It can be applied as a logic test device of a master trip solenoid valve by a channel signal. In addition, the above logic and master trip solenoid valve logic test panel 2
8 is an example. For example, the operation button can be replaced with a switch, and there is no problem even if the status monitoring lamp is common to (A) and (B). Further, the test permission lamps 31a, 3
1b, testing lamps 32a, 32b, valve operation lamp 3
There is no problem even if the lighting and extinguishing logics of 3a and 33b are logics based on signals equivalent to the signals used in FIGS.

[0014]

As described above, conventionally, only a master trip solenoid valve operation confirmation test was performed, and the soundness of a logic circuit from actual turbine trip signal generation to master trip solenoid valve operation can be confirmed. However, according to the present invention, it is possible to confirm the soundness of the logic circuit in addition to the operation test of the conventional master trip solenoid valve. The test logic according to the present invention also
It is a logic that avoids the occurrence of turbine trips due to malfunctions of other master trip solenoid valves during the test, and ensures that turbine trips occur when an actual turbine trip signal is generated, improving reliability and safety. .

[Brief description of the drawings]

FIG. 1 is a system configuration diagram of a turbine protection test apparatus according to an embodiment of the present invention.

FIG. 2 is a test logic diagram of a master trip solenoid valve of the present invention (1).

FIG. 3 is a test logic diagram of the master trip solenoid valve of the present invention (2).

FIG. 4 is a basic configuration diagram of a thermal power plant

FIG. 5 is a configuration diagram of a turbine emergency trip device.

FIGS. 6A and 6B are diagrams illustrating the operation state of a master trip solenoid valve.

FIGS. 7 (c) and (d) are diagrams illustrating the operation state of the master trip solenoid valve.

[Explanation of symbols]

Reference numeral 12: control valve, 12a: main steam stop valve, 13: reheat steam stop valve, 14: generator, 15: mechanical trip signal generating unit, 17: mechanical trip valve, 18: lockout valve, 19: master trip servo Valve, 20
... Hydraulic unit, 21 ... Hydraulic monitoring instrument, 23 ... High pressure oil inflow line, 24 ... High pressure oil supply line, 25a ... Master trip solenoid valve A, 25b ... Master trip solenoid valve B, 26a ... Master trip solenoid valve (A) operation Confirmation switch, 26b: Master trip solenoid valve (B) operation confirmation switch, 27: Central control panel, 28: Master trip solenoid valve logic test panel, 29: Test control / monitoring device, 30: Turbine emergency trip device, 36a: Turbine Trip signal (A), 36a: turbine trip signal (B), 37a: master trip solenoid valve (A) trip position, 37b: master trip solenoid valve (B) trip position, 38a: channel (A) mechanical trip valve operation signal , 38b ... channel (B) mechanical trip valve operation signal, 3 a ... a turbine trip logic (A)
Signal, 39b ... turbine trip logic (B) signal, 40
a: Master trip solenoid valve (A) operation signal, 40b ...
Master trip solenoid valve (B) operation signal, 41: NOT logic, 42a: Test start confirmation timer, 42b: Turbine trip simulation signal timer, 43a: Channel (A) turbine trip simulation signal, 43b: Channel (B) turbine trip simulation Signal, 44a: Channel (A) test start signal, 44b: Channel (B) test start signal, 45a: Channel (A) test master trip solenoid valve operation signal, 45b: Channel (B) test master trip solenoid valve operation signal, 46a: Channel (A) test master trip solenoid valve (A) operating signal; 46b: Channel (B) test master trip solenoid valve (B) operating signal

Claims (5)

[Claims] In a power generation facility in which a turbine trip valve for stopping rotation of a turbine of a power plant is controlled by hydraulic pressure controlled by a plurality of solenoid valves and a servo valve, a test of a specific one of the plurality of solenoid valves is performed. At this time, a turbine trip simulation signal of the actual turbine stop command is generated,
Simultaneously operating the specific solenoid valve using the simulation signal, the turbine trip valve is disabled under the condition that the specific solenoid valve is being tested, and the turbine is stopped without stopping the specific operation. A turbine protection test apparatus characterized by testing an electromagnetic valve according to claim 1. 2. The AND logic according to claim 1, wherein the turbine trip simulation signal and the actual turbine stop command are input to an OR logic, and an AND logic of the OR logic output and a NOT logic signal during the test of the specific solenoid valve is provided. A turbine protection test apparatus, wherein the turbine trip valve is deactivated by an output. 3. The method according to claim 1, wherein a signal of a trip position signal of the specific solenoid valve and a NOT logic signal of the simulation signal are obtained.
The ND signal is input to the OR logic of the operation signals of the other solenoid valves of the plurality, and when the specific solenoid valve is at the trip position, it is regarded as a test state and the other solenoid valves are deactivated. A turbine protection test apparatus, characterized in that: 4. The apparatus according to claim 1, wherein when an actual turbine stop command is issued during a test of a specific solenoid valve among the plurality of solenoid valves, an operation signal of another of the plurality of solenoid valves is output. At the same time, the operation signal of the turbine trip valve is generated on condition that the other solenoid valve is not under test, and the specific solenoid valve and the other solenoid valve are simultaneously operated by the respective operation signals, and the turbine A turbine protection test apparatus characterized by tripping. 5. The turbine protection test apparatus according to claim 1, wherein the operation of the solenoid valve is displayed during the test permission and during the test.