KR102238068B1 - Method for controlling loads of dc power supply systems of nuclear power facilities - Google Patents

Abstract

The load control method of DC power supply systems of nuclear facilities is to control some of the loads of all DC power supply systems of the A, B, C, and D series of the nuclear facility where the AC power loss accident (Station Black Out, SBO) occurred in the first time. Shut off after the second hour from the DC power supply system of the A series, the 7.5kVA inverter load of the A series DC power supply system is cut off after the third time, and the 7.5kVA inverter load of the DC power supply system of the D series is connected. Disconnecting the 7.5kVA inverter load after the fourth hour and connecting the 7.5kVA inverter load of the C series DC power supply system.

Description

How to control loads of DC power supply systems in nuclear facilities {METHOD FOR CONTROLLING LOADS OF DC POWER SUPPLY SYSTEMS OF NUCLEAR POWER FACILITIES}

This description relates to a method of controlling the load of DC power supply systems of a nuclear facility.

In general, nuclear facilities used for nuclear power generation require a plurality of DC power supply systems to supply power to cope with long-term AC power loss accidents (Station Black Out, SBO) due to disasters exceeding design standards. Do.

The DC power supply systems of conventional nuclear facilities consist of four series that are electrically and physically independent from each other, and power is supplied for 2.2 hours to loads required for monitoring and control of the nuclear facility in which an AC power loss accident occurred. Designed to supply.

In one embodiment, without replacing the capacity of the storage battery included in the DC power supply systems, a nuclear power facility that supplies power for 8 hours to loads required for monitoring and control of a nuclear facility in which an AC power loss accident has occurred. It is intended to provide a load control method for DC power supply systems.

One aspect is the A-series DC power supply system, the B-series DC power supply system, the C-series DC power supply system, and the D-series DC power supply that supply power to the nuclear facility in which the AC power loss accident (Station Black Out, SBO) occurred. Blocking some loads of all of the supply systems after a second time from the first time that is the occurrence time of the AC power loss accident, the 7.5kVA inverter load of the A-series DC power supply system after a third time from the first time Blocking and connecting the 7.5kVA inverter load of the D-series DC power supply system, the 7.5kVA inverter load of the B-series DC power supply system is cut off after a fourth hour from the first time, and the C-series DC power supply system Connecting the 7.5kVA inverter load of, and disconnecting the 25kVA inverter load of the A series DC power supply system after a fifth time from the first time and connecting the 25kVA inverter load of the B series DC power supply system It provides a load control method of DC power supply systems of a nuclear facility including.

The second time may be 40 minutes, the third time may be 131 minutes, the fourth time may be 150 minutes, and the fifth time may be 300 minutes.

The 7.5kVA inverter load of the D series DC power supply system connected after the third time from the first time, the 7.5kVA inverter load of the C series DC power supply system connected after the fourth time from the first time, and the It may further include maintaining each 25kVA inverter load of the B series DC power supply system connected after the fifth time from the first time until 480 minutes after the first time.

The A series DC power supply system, the B series DC power supply system, the C series DC power supply system, and the D series DC power supply system may be physically and electrically independent from each other.

Each of the A-series DC power supply system and the B-series DC power supply system includes a storage battery that supplies a safety class DC power of 125V with a capacity of 2415Ah, and each of the C-series DC power supply system and the D-series DC power supply system May contain a storage battery that supplies a 125V safety-grade DC power supply with a capacity of 825Ah.

Each 7.5kVA inverter of the A series DC power supply system, the B series DC power supply system, the C series DC power supply system, and the D series DC power supply system supplies power to the reactor measurement system of the nuclear facility, , The 25kVA inverter of each of the A-series DC power supply system and the B-series DC power supply system may supply power to the reactor protection system of the nuclear facility.

Each 25kVA inverter of the C-series DC power supply system and the D-series DC power supply system may supply power to the residual heat removal system of the nuclear facility.

According to an embodiment, a nuclear facility that supplies power for 8 hours to loads required for monitoring and control of a nuclear facility in which an AC power loss accident occurred without replacing the capacity of the storage battery included in the DC power supply systems. A method of controlling the load of DC power supply systems is provided.

1 is a flow chart showing a load control method of DC power supply systems of a nuclear facility according to an embodiment.
2 is a diagram showing DC power supply systems connected to a nuclear power plant.
3 is a table showing loads by time of a series A DC power supply system in a method of controlling loads of DC power supply systems of a nuclear facility according to an exemplary embodiment.
4 is a graph showing the total load by time of the A-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.
5 is a table showing loads by time of a series B DC power supply system in a load control method of DC power supply systems of a nuclear facility according to an embodiment.
6 is a graph showing the total load by time of the B-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.
7 is a table showing hourly loads of a C-series DC power supply system in a load control method of DC power supply systems of a nuclear facility according to an embodiment.
8 is a graph showing the total load by time of the C-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.
9 is a table showing loads by time of a D-series DC power supply system in a load control method of DC power supply systems of a nuclear facility according to an embodiment.
10 is a graph showing the total load by time of the D-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.

Hereinafter, with reference to the accompanying drawings, an embodiment of the present invention will be described in detail so that those of ordinary skill in the art can easily implement the present invention. The present invention may be implemented in various different forms and is not limited to the exemplary embodiment described herein.

In addition, throughout the specification, when a certain part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

Hereinafter, a load control method of DC power supply systems of a nuclear facility according to an embodiment will be described with reference to FIGS. 1 to 10.

1 is a flow chart showing a load control method of DC power supply systems of a nuclear facility according to an embodiment.

Referring to FIG. 1, first, some loads of all of the A series, B series, C series, and D series DC power supply systems are cut off after a second time period (S100).

2 is a diagram showing DC power supply systems connected to a nuclear power plant.

Referring to FIG. 2, a nuclear power facility 10 supplies four DC power supply systems that are physically and electrically independent from each other, a series A DC power supply system 100, a B series DC power supply system 200, and a C series DC power supply. Each of the system 300 and the D series DC power supply system 400 is connected.

The nuclear facility 10 may be a Westinghouse type pressurized light water reactor type (PWR) nuclear power plant, but is not limited thereto, and may be a boiling light water reactor type (BWR) nuclear power plant. Pressurized light water reactor type nuclear power plants use hard water as a coolant and moderator, and uranium 235 is concentrated to about 2% to 4% for nuclear fuel. A pressurized light water reactor type nuclear power plant is a facility related to a nuclear reactor system that sends heat generated by nuclear fission within the reactor to a steam generator for heat exchange, and a turbine is turned with steam generated from a steam generator, and then reduced to water through a condenser, and then again. It can be divided into facilities related to the turbine and generator systems that are circulated to the steam generator.

A series DC power supply system (100), B series DC power supply system (200), C series DC power supply system (300), and D series DC power supply system (400) each have AC power loss (Station Black Out). , SBO) to supply power to the generated nuclear facility (10).

A series DC power supply system 100, B series DC power supply system 200, C series DC power supply system 300, and D series DC power supply system 400 may be included in the nuclear facility 10, but , But is not limited thereto.

The load control method of the A-series DC power supply system (100), B-series DC power supply system (200), C-series DC power supply system (300), and D-series DC power supply system (400) is to supply A-series DC power supply. It may be performed by a control unit connected to each of the system 100, the B-series DC power supply system 200, the C-series DC power supply system 300, and the D-series DC power supply system 400, but is not limited thereto. Does not.

Each of the A-series DC power supply system 100 and the B-series DC power supply system 200 may include a storage battery for supplying a safety class DC power of 125V with a capacity of 2415Ah.

Each of the C-series DC power supply system 300 and the D-series DC power supply system 400 may include a storage battery that supplies 125V safety-grade DC power with a capacity of 825Ah.

3 is a table showing loads by time of a series A DC power supply system in a method of controlling loads of DC power supply systems of a nuclear facility according to an exemplary embodiment.

4 is a graph showing the total load by time of the A-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.

3 and 4, the A-series DC power supply system includes a 7.5kVA inverter, a 25kVA inverter, an emergency diesel generator starting system, a 4.16kV breaker control, a 480V load control, a reactor stop switch gear, a semiconductor logic protection system, and RCP. (Nuclear reactor coolant pump) Power is supplied by time to loads including stop circuit breaker control and pressurizer pressure release valve control.

5 is a table showing loads by time of a series B DC power supply system in a load control method of DC power supply systems of a nuclear facility according to an embodiment.

6 is a graph showing the total load by time of the B-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.

5 and 6, the B-series DC power supply system includes a 7.5kVA inverter, a 25kVA inverter, an emergency diesel generator starting system, a 4.16kV breaker control, a 480V load control, a reactor stop switch gear, a semiconductor logic protection system, and RCP. (Nuclear reactor coolant pump) Power is supplied by time to loads including stop circuit breaker control and pressurizer pressure release valve control.

7 is a table showing hourly loads of a C-series DC power supply system in a load control method of DC power supply systems of a nuclear facility according to an embodiment.

8 is a graph showing the total load by time of the C-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.

7 and 8, the C-series DC power supply system includes a 7.5kVA inverter, a 25kVA inverter, a turbine-driven auxiliary feed water pump valve control and speed control, a reactor coolant pump (RCP) stop circuit breaker control, and a power plant isolation relay panel. Power is supplied by time to the loads.

9 is a table showing loads by time of a D-series DC power supply system in a load control method of DC power supply systems of a nuclear facility according to an embodiment.

10 is a graph showing the total load by time of the D-series DC power supply system in the load control method of the DC power supply systems of a nuclear facility according to an embodiment.

9 and 10, the D-series DC power supply system supplies power to loads including a 7.5kVA inverter, a 25kVA inverter, and a power plant isolation relay panel by time.

3 to 10, each 7.5kVA inverter of the A-series DC power supply system, the B-series DC power supply system, the C-series DC power supply system, and the D-series DC power supply system is connected to the reactor measurement system of a nuclear facility. Supply power.

Here, the nuclear instrumentation system is a nuclear instrumentation system (measurement of nuclear reactor output, radiation dose, etc.), a reactor protection system (measurement control power supply of the temperature, pressure and flow rate of the reactor coolant system, water level and pressure of the steam generator), and semiconductor logic protection. The panel power supply of the system may be included, but is not limited thereto.

Each 25kVA inverter of the A series DC power supply system and the B series DC power supply system supplies power to the reactor protection system of the nuclear facility.

Here, the reactor protection system may include, but is not limited to, a cabinet power supply of a semiconductor logic protection system, a main control room (MCR) cabinet power supply, a main control room (MCR) board power supply, and the like.

Each 25kVA inverter of the C-series DC power supply system and the D-series DC power supply system supplies power to the residual heat removal system of nuclear facilities.

Here, the residual heat removal system may include a residual heat removal system (RHRS) inlet valve actuator operation power supply, but is not limited thereto.

3 to 10, the A-series DC power supply system, the B-series DC power supply system, and the C-series DC power supply system supplying power to a nuclear facility in which an AC power loss accident (Station Black Out, SBO) has occurred. Some loads of both the, and D-series DC power supply systems are cut off after the second time (40 minutes) from the first time (0 minutes), which is the occurrence time of the AC power loss accident.

Specifically, the 7.5kVA inverter of the A-series DC power supply system, the 25kVA inverter, and the remaining loads excluding the semiconductor-type logic protection system load are cut off after the second time (40 minutes), and the 7.5kVA inverter of the B-series DC power supply system And the rest of the loads excluding the load of the semiconductor-type logic protection system and the other loads excluding the load of the turbine-driven auxiliary feed water pump valve control and speed control of the C-series DC power supply system and the power plant isolation relay panel load after the second time (40 minutes). They are cut off after the second time (40 minutes), and the rest of the loads except for the power plant isolation relay panel load of the D series DC power supply system are cut off after the second time (40 minutes). Here, the interruption after the second time (40 minutes) is 30 minutes after the first time (0 minutes), which is the occurrence time of the AC power loss accident (SBO), after the long-term AC power loss accident is declared, the load is cut off and the required time is 10 minutes. It can be done after.

In other words, 30 minutes after the first time (0 minutes), which is the occurrence time of the AC power loss accident (SBO), it is declared as a long-term AC power loss accident, and after the second time (40 minutes), 10 minutes later, the A-series DC power supply system Block loads other than the 7.5kVA inverter and 25kVA inverter load, the loads other than the 7.5kVA inverter load of the B series DC power supply system, the loads of the C series DC power supply system, and the D series DC power supply system loads.

Next, referring to FIG. 1, the 7.5kVA inverter load of the A-series DC power supply system is cut off after a third time and the 7.5kVA inverter load of the D-series DC power supply system is connected (S200).

Specifically, referring to FIGS. 3, 4, 9, and 10, the 7.5kVA inverter load of the A-series DC power supply system is cut off after the third time (131 minutes) from the first time (0 minutes) and D Connect the 7.5kVA inverter load of the series DC power supply system.

That is, after the third time (131 minutes) from the first time (0 minutes), the 7.5kVA inverter load of the A-series DC power supply system is replaced with the 7.5kVA inverter load of the D-series DC power supply system.

Next, referring to FIG. 1, the 7.5kVA inverter load of the B-series DC power supply system is cut off after the fourth time and the 7.5kVA inverter load of the C-series DC power supply system is connected (S300).

Specifically, referring to Figs. 5 to 8, the 7.5kVA inverter load of the B-series DC power supply system is cut off after the fourth time (150 minutes) from the first time (0 minutes), and the 7.5kVA of the C-series DC power supply system is Connect the kVA inverter load.

That is, after the first time (0 minutes) to the fourth time (150 minutes), the 7.5kVA inverter load of the B series DC power supply system is replaced with the 7.5kVA inverter load of the C series DC power supply system.

Next, referring to FIG. 1, the 25kVA inverter load of the A-series DC power supply system is cut off after 5 hours, and the 25kVA inverter load of the B-series DC power supply system is connected (S400).

Specifically, referring to FIGS. 3 to 6, the 25kVA inverter load of the A series DC power supply system is cut off after the fifth time (300 minutes) from the first time (0 minutes) and the 25kVA inverter of the B series DC power supply system Connect the load.

That is, the 25kVA inverter load of the A-series DC power supply system is replaced with a 25kVA inverter load of the B-series DC power supply system after the fifth time (300 minutes) from the first time (0 minutes).

Next, referring to FIG. 1, the 7.5kVA inverter load of the D series and C series DC power supply systems and the 25kVA inverter load of the B series DC power supply system are maintained until 480 minutes later (S500).

Specifically, referring to FIGS. 5 to 10, the 7.5kVA inverter load of the D-series DC power supply system connected after the first time (0 minutes) to the third time (131 minutes), the first time (0 minutes) Each of the 7.5kVA inverter load of the C series DC power supply system connected after 4 hours (150 minutes) and the 25kVA inverter load of the B series DC power supply system connected after the fifth time (300 minutes) from the first time (0 minutes) It is held until 480 minutes after the first time (0 minutes).

That is, the 7.5kVA inverter load of the D series DC power supply system replaced after the third time (131 minutes), the 7.5kVA inverter load of the C series DC power supply system replaced after the fourth time (150 minutes), the fifth time ( 300 minutes), the 25kVA inverter load of the replaced B series DC power supply system is maintained until 480 minutes later.

As described above, the load control method of the DC power supply systems of a nuclear facility according to an embodiment is, without changing the capacity of the storage batteries included in the DC power supply systems, the A-series DC power supply system, the B-series DC power supply system, By linking the inverter loads of the C-series DC power supply system and the D-series DC power supply system, the loads required for monitoring and control of the nuclear facility in which a long-term AC power loss accident (SBO) has occurred are 480 instead of the existing 2.2 hours. It can supply power for 8 hours (minutes).

In addition, the load control method of the DC power supply systems of a nuclear facility according to an embodiment is the continuous monitoring of the power plant status, essential equipment and measurement control according to the regulatory guidelines for domestic nuclear power plants (KINS/RG-N09.19 long-term AC power loss accident). It satisfies the requirement that the usable capacity of the storage battery that supplies power must be secured for at least 8 hours and that the operator must take action after 30 minutes of an AC power loss accident (SBO).

In addition, the load control method of the DC power supply systems of a nuclear facility according to an embodiment replaces the existing safety grade storage battery with a storage battery with excellent supply capacity and performance, or expands the capacity of the existing storage battery with a safety grade secured by four times. It reduces the enormous facility improvement cost required to do so.

In other words, DC power supply of nuclear facilities that supplies power for 8 hours to loads required for monitoring and control of nuclear facilities in which AC power loss accidents occur without replacing the capacity of the storage batteries included in the DC power supply systems. A method of controlling the load of systems is provided.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Nuclear facilities (10), A series DC power supply system (100), B series DC power supply system (200), C series DC power supply system (300), D series DC power supply system (400)

Claims (7)

A series DC power supply system, a B series DC power supply system, a C series DC power supply system, and a D series DC power supply system supplying power to a nuclear facility in which an AC power loss accident (Station Black Out, SBO) occurred. Blocking some loads of the AC power loss after a second time from the first time which is the occurrence time of the AC power loss accident;
Disconnecting the 7.5kVA inverter load of the A series DC power supply system after a third time from the first time period and connecting the 7.5kVA inverter load of the D series DC power supply system;
Disconnecting the 7.5kVA inverter load of the B series DC power supply system after a fourth time from the first time period and connecting the 7.5kVA inverter load of the C series DC power supply system; And
Blocking the 25kVA inverter load of the A series DC power supply system after a fifth time from the first time period and connecting the 25kVA inverter load of the B series DC power supply system
Including,
Each 7.5kVA inverter of the A series DC power supply system, the B series DC power supply system, the C series DC power supply system, and the D series DC power supply system supplies power to the reactor measurement system of the nuclear facility, ,
The 25kVA inverter of each of the A-series DC power supply system and the B-series DC power supply system supplies power to the nuclear reactor protection system of the nuclear facility. In claim 1,
The second time is 40 minutes,
The third time is 131 minutes,
The fourth time is 150 minutes,
The fifth time is 300 minutes, the load control method of DC power supply systems of a nuclear power facility. In claim 1,
The 7.5kVA inverter load of the D series DC power supply system connected after the third time from the first time, the 7.5kVA inverter load of the C series DC power supply system connected after the fourth time from the first time, and the The load control method of DC power supply systems of a nuclear facility further comprising maintaining each 25kVA inverter load of the B series DC power supply system connected after the first time to the fifth time until 480 minutes after the first time. . In claim 1,
The A-series DC power supply system, the B-series DC power supply system, the C-series DC power supply system, and the D-series DC power supply system are physically and electrically independent from each other. . In claim 1,
Each of the A-series DC power supply system and the B-series DC power supply system includes a storage battery for supplying a safety class DC power of 125V with a capacity of 2415Ah,
Each of the C-series DC power supply system and the D-series DC power supply system includes a storage battery that supplies 125V safety-grade DC power with a capacity of 825 Ah. delete In claim 1,
The 25kVA inverter of each of the C-series DC power supply system and the D-series DC power supply system supplies power to the residual heat removal system of the nuclear facility.

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