JPS6373287A - Governor simulator - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention relates to a governor simulator device, and particularly to a governor simulator device that is optimal for fault training for governor control devices in hydroelectric power plants. It is.

(Prior art) Various plants have recently become larger and more sophisticated with the development of digital control devices and the expansion of computer applications.In the heavy electrical sector, especially hydroelectric power plants, thermal
Pumped storage power plants are becoming mainstream as nuclear couplants become larger, and they are equipped with multiple units to increase capacity. In addition, the operation modes of the plant are power generation operation, pumping operation, and phase adjustment operation.

Test power transmission operations are diversified, and each operation is fully automated by applying various automatic controls such as startup control, flow rate control, AFC control, ALR control, AQR control, individual operation control, and program operation control. There is. Therefore, the control devices necessary for controlling these operations are becoming more complex and highly functional.

By the way, hydroelectric power plants are unmanned, and regular operation is carried out by one person from a remote control station, so if the control equipment breaks down or if manual operation is performed at the power plant during inspections, Operators need regular training to understand the contents of the control device well and to take appropriate measures in the event of a failure of the control device.

However, current plant simulators for the purpose of operator training create dynamic models for pump-turbines, generator motors, etc.
Various amounts of electricity from generator motors.

Although methods such as displaying quantitative data such as the hydraulic system of the governor control device on a CRT or moving instruments on the monitoring control panel have been applied,
No method has been applied to check the main engine status at the time of a control equipment failure using instruments on the supervisory control panel, or to conduct training to discover the cause with a sense of realism. Therefore, the reality is that the corresponding training for the control device is simply based on learning based on control block diagrams and drawings.

(Problems to be Solved by the Invention) As described above, in the conventional simulator device, failures in the governor control device are simulated, and the failure state is displayed on the instrument on the panel, and the failure state is displayed in the case of failure of the governor control device. There is a problem in that it is not possible to conduct training on the movement of the main engine or to discover the cause of failures in the governor control device in a sense of urgency.

Therefore, in the present invention, a failure of the governor control device is simulated and the failure state is displayed on the board to train the movement of the main engine in the event of a failure of the governor control device, and training to discover the cause of the failure of the governor control device is conducted as an extraordinary training. The object of the present invention is to provide a highly reliable governor simulator device that can perform the following tasks.

[Structure of the Invention] (Means for Solving the Problems) In order to achieve the above object, a governor simulator device according to the present invention includes a simulation panel for monitoring and controlling the state of a plant, a sequence control circuit for the plant, and a governor simulator device according to the present invention. It consists of a plant simulator device that simulates the state of various electric quantities and mechanical quantities in the plant and sends the simulated quantities to the above-mentioned simulation board, and various analog boards, and changes the guide vanes of the water turbine to change the rotational speed and output of the main engine. a governor control device for adjusting the
It consists of a fault setting device equipped with a switch for setting a simulated fault location on the board during fault training for this governor control device, and a hardware testing device equipped with a simulated power supply device for detecting the fault location of the governor control device. It is characterized by being made to do.

(Function) In the governor simulator device described above, during fault training for the governor control device, by setting a fault in the governor control device from the fault setting device, the state of the main engine can be simulated on the mock board using signals from the plant simulator device. This enables the state of the main engine at the time of failure of the governor control device to be realized, and by checking the current and voltage of the board of the governor control device using the hardware testing device, it is possible to trace the location of the failure.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 shows in block form an example of the configuration of a governor simulator device according to the present invention. In Figure 1, 1
2 is a mock panel equipped with switches and instruments for monitoring and controlling the status of the plant; 2 is a mock panel that simulates the status of the plant's sequence control circuit and various electrical and mechanical quantities; A plant simulator device 3 is used as a basis for failure training of a governor control device 4 which will be described later, and a governor control device 5 is used to adjust the rotational speed and output of the main engine by varying the guide blades of the water turbine. This is a node testing device that is equipped with a simulated power supply device for detecting failure locations, and a digiport, tester, etc.

FIG. 2 shows an example of a circuit configuration for setting a simulated failure location on the board of the governor control device 4, the details of which will be described later. In FIG. 2, normally open contact switches Ao and Bo' are provided in the fault setting device 3.

Co...Ho are provided in the governor control device 4.

Auxiliary relay A for contacts Ab, Bb, Cb, ..., Hb to control the signal flow between the analog boards
, B, C, . . . , H are connected in series between the DC control power supply buses P and N.

FIG. 3 shows an example of the internal configuration of the governor control device 4 and an example of the connection configuration between the governor control device 4 and the hardware testing device 5. In FIG. 3, a simulated input voltage is input from the simulated power supply device 21 in the hardware test device 5 to the F/V converter board 11 in the governor control device 4, and the level-converted signal is transmitted to the F/V converter board 11 in the case of a normally closed fault. The signal is input to the ΔF detector board 12 via the simulated contact Ab, and the level-converted signal is input to the droop rate calculator board 14 via the normally closed fault simulated contact Bb.
Enter. In addition, the signal from the load setting device board 13 is
Droop rate calculator board 14 via normally closed failure simulation contact cb
Enter. Furthermore, after inputting the signal from the GV return resistor 23 in the hard test device 5 to the position detector board 17 in the governor control device 4 and converting the level, Input to the rate calculator board 14.

On the other hand, the signal from the droop rate calculator board 14 is input to the PID calculator board 15 via the normally closed fault simulating contact Db, and the level-converted signal is inputted here via the normally closed fault simulating contact Eb. and input it to the amplifier board 16. Further, the signal whose level has been converted by the amplifier board 16 is inputted to the converter coil 22 in the hardware testing device 5 via the normally closed failure simulating contact Fb. Furthermore, the simulated power supply from the simulated power supply device 21 is input to the power supply device 18 in the governor control device 4, and the level-converted control power supply is sent to each of the above-mentioned boards via the normally closed failure simulation contact Hb. I am trying to input it.

Next, the operation of the governor simulator device according to this embodiment will be explained.

For main engine operation, by first operating switches (not shown) on the simulation panel 1, the plant control process is simulated in the plant simulator device 2, and various changes such as the main engine rotational speed and the opening of the guide vanes of the water turbine are performed. The plant state is simulated, and the simulated amount is displayed on a meter (not shown) on the simulation panel 1. In the plant simulator device 2, a control circuit equivalent to the governor control device 4 is dynamically modeled.

Therefore, when training various board failures of the governor control device 4 using the fault setting device 3, the details of the fault are input from the fault setting device 3 to the plant simulator device 2, and the plant simulator device 2 A plant state caused by a board failure is simulated, and this is displayed on a meter (not shown) on the simulation panel 1, or a failure indicator is operated.

On the other hand, when searching for a faulty location in the governor control device 4, the search starts after confirming that the main engine has stopped using an operation indicator (not shown) on the mock panel 1. Prior to searching for a failure location in the governor 1=J control device 4, the instructor operates an arbitrary switch of the failure setting device 3 to simulate a failure of the circuit board in the governor control device 4. here,
Setting the board failure of the ΔF detector board 12 will be described.

That is, first, the instructor operates switch Bo of fault setting device 3, thereby operating auxiliary relay B and opening its normally closed contact Bb. The trainee uses the hard test device "5" to search for the failure location of the governor control device 4.
from the simulated power supply device 21 of the governor control device 4 to the power supply device 1 of the governor control device 4.
Step 8: Input the power and utilize the governor control power. Also,
The trainee performs the task of inputting a voltage corresponding to the rotational speed of the main engine from the simulated power supply device 21 to the F/V converter board 11 of the governor control device 4 in a simulated manner. The trainee then uses a tester or the like to measure the output voltages of various boards to locate the location of the failure. In this case, when detecting a fault in the ΔF detector board 12, it is found that while the simulated input is present at the input part of the ΔF detector board 12, there is no input voltage to the droop rate calculator board 14.

As described above, in this embodiment m, the plant simulator device 2 uses the simulated board 1 that monitors and controls the state of the main engine of the plant and the fault setting device 3 that sets the fault location of the governor control device 4 to detect the plant. Since the plant status is simulated and displayed on the mock board, the trainee can confirm the movement of the entire plant.

Furthermore, when searching for a faulty location in the governor control device 4, it is possible to trace the faulty location by wiring test wires and measuring the board voltage with a tester or the like in the same way as in actual work at the site. Therefore, training can be performed with a sense of realism, and the effectiveness of training can be greatly increased.

In the above embodiment, the fault setting device 3 is operated by operating a switch, which is a movable contact. The same effect as described above can be obtained by inputting the signal to the plant simulator device 2 and operating the auxiliary relay for fault setting in the governor control device 4 via the output converter from the plant simulator device 2. .

In addition, the present invention can be modified and implemented in various ways without changing the gist thereof.

[Effects of the Invention] As explained above, according to the present invention, a simulation panel for monitoring and controlling the state of a plant, a sequence control circuit of the plant, and a state of each of 8 electrical quantities and 2 mechanical quantities of the plant are simulated, A plant simulator device that sends the simulated amount to the simulation board, a governor control device that is composed of various analog boards and that adjusts the rotation speed and output of the main engine by varying the guide vanes of the water turbine, and a failure of this governor control device. It consists of a fault setting device equipped with a switch for setting a simulated fault location on the board during training, and a hardware testing device equipped with a simulated power supply device for detecting the fault location of the governor control device. To simulate the failure of the governor control device and display the failure state on the board to train the main engine movement in the event of a failure of the governor control device, and to conduct training to discover the cause of failure of the governor control device with a sense of urgency. It is possible to provide an extremely reliable governor simulator device that is capable of

[Brief explanation of the drawing]

FIG. 1 is a configuration block diagram showing an embodiment of a governor simulator device according to the present invention, FIG. 2 is a circuit configuration diagram for setting a failure location of a governor control device in the same embodiment, and FIG. 3 is a configuration block diagram of a governor control device in the same embodiment. FIG. 2 is a circuit diagram showing an example of a connection configuration between a control device and a hardware test device. 1...Mock board, 2...Plant simulator device,
3...Failure setting device, 4...Governor control device, 5.
...Node test equipment, 11...F/V converter board,
DESCRIPTION OF SYMBOLS 12...ΔF detector board, 13... Load setting device board, 14... Drooping rate calculator board, 15... PID calculator board, 16... Amplifying lid board, 17... Position detector board, 18... power supply device, 21... simulated power supply device,
22... Converter coil, 23... GV trace resistor, AO2Bo, Co, Do, Eo, Fo, Go,
Ho---fault setting switch, A, B, C, D, E, F
,G. H...Auxiliary relay for failure setting, Ab, Bb, Cb. Db, Eb, Fb, Gb, Hb... Normally closed contact of auxiliary relay for failure setting, P, N... DC control power supply bus. Applicant's agent Patent attorney Takehiko Suzue Figure 1

Claims (1)

[Claims] A mock panel for monitoring and controlling plant conditions, plant sequence control circuits, and various amounts of electricity in the plant.
A governor control device that is composed of a plant simulator device that simulates the state of mechanical quantities and sends the simulated quantities to the simulation board, and various analog boards, and that adjusts the rotation speed and output of the main engine by varying the guide vanes of the water turbine. A hardware test device includes a fault setting device including a switch for setting a simulated fault location on the board during fault training of the governor control device, and a simulated power supply device for detecting the fault location of the governor control device. A governor simulator device comprising: