KR20220138755A - Control System for safety injection flow to prevent high level of steam generator - Google Patents

Abstract

A safety injection control system for preventing a high water level of a steam generator according to the present invention includes: a pressurizer water level transmission unit transmitting a pressurizer water level value; a steam generator water level transmission unit transmitting a steam generator water level value; a signal conversion unit receiving the pressurizer water level value and the steam generator water level value, comparing the pressurizer water level value and the steam generator water level value, and generating and transmitting a conversion signal including relative water level information; a main controller receiving the conversion signal to generate and transmit a valve control signal for adjusting a degree of opening of a safety injection flow control valve to control a safety injection flow rate; and a valve controller receiving the valve control signals to open and close the safety injection flow control valve. The safety injection control system automatically adjusts the safety injection flow rate to prevent a high steam generator water level caused by excessive injection when a steam generator tube is broken.

Description

Safety injection control system to prevent high level of steam generator {Control System for safety injection flow to prevent high level of steam generator}

The present invention relates to a safety injection control system for preventing high water level in a steam generator, and in particular, a safety injection control system for preventing high water level in a steam generator by automatically adjusting the safety injection flow rate when the heat pipe of the steam generator is broken to prevent the high level of the steam generator is about

The steam generator of a nuclear power plant receives high-temperature coolant from the reactor coolant system through a bundle of heat transfer tubes. If the heat transfer tube ruptures, the reactor coolant leaks to the steam generator, and the stock of reactor coolant rapidly decreases and the water level in the steam generator increases. Accordingly, the safety injection system is operated to replenish the stock of the reactor coolant system. However, in the case of an accident (Multiple Steam Generator Tube Rupture, MSGTR) in which several heat transfer tubes are ruptured, the safety injection flow rate is also large due to leakage of a large amount of reactor coolant. The existing safety injection system is difficult to control because the safety injection flow rate is determined according to the pressure of the reactor coolant system, and there is no means to automatically prevent the steam generator full level.

Specifically, the safety injection system generates a safety injection signal when the pressure in the reactor coolant system is reduced below the set value, and the safety injection flow rate (hereinafter referred to as supplemental coolant) is generated according to the difference between the safety injection pump head pressure and the reactor coolant pressure. ) to replenish the reactor coolant. The safety injection system performs an important function in preventing damage from exposure to nuclear fuel in a reactor coolant loss accident in the same way as above.

In the event of a heat pipe breakage accident in the steam generator, and no action is taken by the operator, the reactor coolant flows continuously to the steam generator, and the coolant level in the core is maintained as the amount of the leaked reactor coolant is replenished from the safety injection system. Residual heat removal of the core is performed without any problem. However, the water level of the steam generator continuously rises due to the supplemental coolant introduced into the steam generator through the fracture site, and when the high level set value of the steam generator is reached, the main steam isolation is automatically performed. When the main steam isolation occurs, the flow path of the steam discharged from the steam generator is all blocked, the pressure rises, and the main steam safety valve is continuously opened as the pressure rises. In order to prevent the reactor coolant containing radioactive materials from being continuously released into the atmosphere through the breakage part of the heat pipe and the main steam safety valve, the operator manually controls and operates the safety injection at a sufficient level of the reactor coolant stock in the primary and secondary sides. By balancing the pressure on the secondary side, the reactor coolant is no longer leaked from the fracture surface of the steam generator heat pipe.

If one of the heat transfer tubes of the steam generator is broken and the coolant leaks out, the loss of the reactor coolant is not large and the reduction rate of the reactor coolant is also small. In this case, it is relatively easy for the operator to balance the primary and secondary pressures through manual operation. However, in the case of the MSGTR in which a plurality of heat transfer tubes are ruptured, the leakage of reactor coolant is large, and a relatively large amount of supplementary coolant needs to be injected, which makes it difficult for the operator to manually adjust the safety injection. In addition, since the water level of the steam generator rapidly increases due to the breaking flow rate that is leaked due to the breakage of the heat transfer tube, there is a possibility that the full water level of the steam generator may be caused if the time of operator intervention is delayed.

The present invention has been devised to solve the above needs, and provides a safety injection control system for preventing high water level in a steam generator by automatically adjusting the safety injection flow rate when the heat pipe of the steam generator is broken to prevent the high level of the steam generator. is for that purpose.

A safety injection control system for preventing a high water level in a steam generator according to an aspect of the present invention includes: a pressurizer water level transmission unit for transmitting a water level value of the pressurizer; Steam generator water level transmission unit for transmitting the water level value of the steam generator; a signal conversion unit for receiving the pressurizer water level value and the steam generator water level value, and generating and transmitting a conversion signal including relative water level information obtained by comparing and determining the pressurizer water level value and the steam generator water level value; a master controller that receives the switching signal and generates and transmits a valve control signal for controlling an opening degree of a safety injection flow rate control valve for controlling a safe injection flow rate; and a valve controller that receives the valve control signal and opens and closes the safety injection flow rate control valve.

In addition, it includes a water level information storage unit for storing the water level value of the steam generator, the main controller, based on the water level information storage unit, when the rate at which the water level of the steam generator increases, in proportion to the increase rate Preferably, the valve control signal is generated to close the valve.

In addition, the steam generator water level value is converted into a predetermined form for comparison with the pressurizer water level value, and the conversion signal is derived by the difference value of the converted steam generator water level value from the pressurizer water level value, the difference value In the case of this negative (-) value, it is preferable that the water level of the steam generator is determined to be relatively high, and the main controller generates a valve control signal to close the valve, thereby reducing the safety injection flow rate.

On the other hand, according to another aspect of the present invention, a safety injection control system for preventing high water level in a steam generator includes: a pressurizer water level transmission unit for transmitting a water level value of a pressurizer; a pressurizer water level signal conversion unit for generating and transmitting a pressurizer water level signal including relative pressurizer water level information by comparing the pressurizer water level value with a predetermined pressurizer water level setting value; Steam generator water level transmission unit for transmitting the water level value of the steam generator; a high water level detecting unit for detecting whether the water level of the steam generator is a high level; 1) when the water level of the steam generator does not reach a predetermined high level, a switching signal based on the pressurizer water level signal is generated and transmitted, or 2) the water level of the steam generator is set to a predetermined high level by the high level detection unit When it is determined, a signal conversion unit for selectively generating and transmitting a conversion signal including the relative water level information obtained by comparing the water level value of the pressurizer and the water level value of the steam generator; a master controller for generating and transmitting a valve control signal for regulating the opening degree of a safety injection flow rate control valve for regulating the safe injection flow rate by receiving the singi switching signal; and a valve controller that receives the valve control signal and opens and closes the safety injection flow rate control valve.

Here, including a water level information storage unit for storing the water level value of the steam generator, wherein the main controller, based on the water level information storage unit, when the rate at which the water level of the steam generator increases, in proportion to the increase rate Preferably, the valve control signal is generated to close the valve.

Here, when the signal conversion unit generates a switching signal in a situation where the water level of the steam generator is high, the steam generator water level value is converted into a predetermined form for comparison with the pressurizer water level value, and the steam generator water level value is converted into a predetermined form for comparison with the pressurizer water level value, and the conversion signal is derived from the difference value of the converted steam generator water level value from the pressurizer water level value, and the difference value is a negative (-) value In this case, it is preferable that the water level of the steam generator is determined to be relatively high, and the main controller generates a valve control signal to close the valve, thereby reducing the safety injection flow rate.

The safety injection control system for preventing high water level in a steam generator according to the present invention provides an effect of preventing the high level of the steam generator due to excessive safety injection by automatically adjusting the safety injection flow rate when the heat pipe of the steam generator is broken.

1 is a block diagram of a safety injection control system according to an embodiment of the present invention;
2 is a block diagram of a safety injection control system according to another embodiment of the present invention.

Hereinafter, various embodiments of the present invention will be described in connection with the accompanying drawings. Various embodiments of the present invention can be made various changes and can have various embodiments, specific embodiments are illustrated in the drawings and the related detailed description is described. However, this is not intended to limit the various embodiments of the present invention to specific embodiments, and should be understood to include all changes and/or equivalents or substitutes included in the spirit and scope of various embodiments of the present invention. In connection with the description of the drawings, like reference numerals have been used for like components.

Expressions such as “comprises” or “may include” that may be used in various embodiments of the present invention indicate the existence of a corresponding disclosed function, operation, or component, and may include one or more additional functions, operations, or components, etc. are not limited. In addition, in various embodiments of the present invention, terms such as "comprise" or "have" are intended to designate that a feature, number, step, action, component, part, or combination thereof described in the specification is present, It should be understood that it does not preclude the possibility of addition or existence of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

When a component is referred to as being “connected” to another component, the component may be directly connected to the other component, but a new component is formed between the component and the other component. It should be understood that there may be On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it will be understood that no new element exists between the element and the other element. should be able to

Terms used in various embodiments of the present invention are only used to describe a specific embodiment, and are not intended to limit various embodiments of the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by those of ordinary skill in the art to which various embodiments of the present invention pertain.

Terms such as those defined in commonly used dictionaries should be interpreted as having meanings consistent with the meanings in the context of the related art, and unless explicitly defined in various embodiments of the present invention, ideal or excessively formal terms not interpreted as meaning

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Figure 1 is a block diagram of a safety injection control system according to an embodiment of the present invention, Figure 2 is a block diagram of a safety injection control system according to another embodiment of the present invention.

The present invention relates to a safety injection control system for preventing a high water level in a steam generator when a heat transfer tube of the steam generator is broken. The safety injection system delivers flow from the safety injection source to the reactor coolant system, which is regulated by closing the throttling valve. Conventional throttling valves can only open and close according to the safety injection signal, and are designed to be passively operated according to the state of the nuclear power plant.

The safety injection control system for preventing high water level in a steam generator according to the present invention compares the water level of the pressurizer with the water level of the steam generator to control the safe injection flow rate. During operation of a nuclear power plant, there is no direct relationship between the water level in the pressurizer and the water level in the steam generator under normal conditions. phenomenon occurs. According to the present invention, the high water level of the steam generator is prevented in advance by reducing the safe injection flow rate as the water level of the steam generator increases when the heat transfer tube is broken as described above.

In case of leakage of coolant other than the breakage of the heat pipe, the safe injection method can be maintained as in the prior art by opening and closing the throttling valve. can be In addition, it is possible to recognize the control for the non-breaking leakage accident of the heat pipe and the control for the leakage accident due to the breakage of the heat pipe, and automatically switch the control system to each other. When the following heat pipe breakage accident is detected, it can be automatically switched to the control system according to the present invention.

When the heat transfer tube is broken, the pressure of the pressurizer does not increase, but it is lower than the set value and maintains an unstabilized state. In particular, when one heat pipe is broken (SGTR), one or more of the following symptoms may be accompanied. A high radiation alarm may occur in the secondary system or the radiation may increase abnormally. The water level may be inconsistent during the steam generation period or the feed water flow rate may be inconsistent during the steam generation period. In addition, the flow rate of the steam generated by the steam generator and the feed water supplied may be inconsistent. In such a symptom, if the pressure drop of the pressurizer and the water level mismatch of the steam generator appear faster than the symptom in which the single heat pipe is broken, it can be determined as Multiple Steam Generator Tube Rupture (MSGTR) in which several heat pipes are broken. . On the other hand, when only the pressure of the pressurizer is reduced, it may be determined as a non-breakable leakage accident of the heat transfer tube.

Referring to Figure 1, the safety injection control system for preventing high water level in the steam generator according to an aspect of the present embodiment, the pressurizer water level transmission unit 10, the steam generator water level transmission unit 20, the signal conversion unit 30, the main control a group 40 , and a valve controller 50 .

The pressurizer water level transmission unit 10 transmits the water level value of the pressurizer, and the steam generator water level transmission unit 20 transmits the water level value of the steam generator.

The signal conversion unit 30 receives the pressurizer water level value and the steam generator water level value, and compares and determines the pressurizer water level value and the steam generator water level value to generate a conversion signal including the relative level information of both obtained and transmit. According to this embodiment, the signal conversion unit 30 converts the steam generator water level value into a predetermined form in order to compare the pressurizer water level value and the steam generator water level value. Of course, the pressurizer water level value may be converted into a predetermined form and compared with the steam generator water level value.

The conversion signal generated by the signal conversion unit 30 is derived based on a difference value between the converted steam generator water level value in the pressurizer water level value. When the difference value has a negative (-) value, it is determined that the water level value of the steam generator is relatively high compared to the water level value of the pressurizer. As such, when the difference value has a negative value, the supplied safety injection flow rate is controlled in a decreasing direction. On the other hand, when the water level of the pressurizer is lower than a predetermined value, the safe injection flow rate is controlled in an increasing direction. For example, when the water level of the pressurizer is too low, even if the water level of the steam generator is high, the safety injection flow rate may be controlled in a direction to increase.

The main controller 40 receives the switching signal to generate and transmit a valve control signal for controlling the opening degree of the safety injection flow rate control valve 60 for adjusting the safe injection flow rate. For example, when the switching signal is a negative value, the main controller 40 generates a valve control signal to close the safety injection flow rate control valve 60 so that the injected safety injection flow rate can be reduced. And, according to this embodiment, the main controller 40 is used as a PI controller.

The valve controller 50 opens and closes the safety injection flow rate control valve 60 by receiving the valve control signal transmitted from the main controller 40 . When the heat pipe is broken and the water level of the steam generator rises to a relatively higher level than the water level of the pressurizer, the main controller 40 generates a valve control signal to close the safety injection flow rate control valve 60, so it is received The valve controller 50 controls the valve in a direction to reduce the injected safety injection flow rate by operating the safety injection flow rate control valve 60 in a closing direction.

The safety injection control system for preventing the high water level of the steam generator according to the present embodiment includes a water level information storage unit 70 for storing the water level value of the steam generator. The main controller 40, based on the water level information of the steam generator stored in the water level information storage unit 70, when the rate at which the water level of the steam generator increases increases, the safety injection in proportion to the increase rate The valve control signal is generated so that the flow control valve 60 is closed. Due to this, the safety injection flow rate control valve 60 is quickly closed in proportion to the speed at which the water level of the steam generator increases, thereby solving the problem that the full water level of the steam generator is caused due to the late operator intervention.

On the other hand, the safety injection control system for preventing the high level of the steam generator according to another aspect of the present invention, the control method of the safety injection flow control valve 60 for preventing the high level of the steam generator according to whether the high level of the steam generator is different. can In the present embodiment, the same reference numerals are assigned to components having the same functions as those in the embodiment of FIG. 1 .

As shown in FIG. 2, according to this embodiment, the pressurizer water level transmission unit 10, the pressurizer water level signal conversion unit 80, the steam generator water level transmission unit 20, the high water level detection unit 90, the signal conversion unit 30 , a main controller 40 , and a valve controller 50 .

The pressurizer water level transmitting unit 10 and the steam generator water level transmitting unit 20 are provided to transmit the water level value of the pressurizer and the water level value of the steam generator, respectively, as in the embodiment of FIG. 1 .

The pressurizer water level signal conversion unit 80 is provided to generate and transmit a pressurizer water level signal including relative pressurizer water level information by comparing the pressurizer water level value with a predetermined pressurizer water level setting value. The pressurizer water level signal conversion unit 80 is provided to remove the safe injection flow rate only with the pressurizer water level value.

The high water level detection unit 90 is provided to detect whether the water level of the steam generator is a predetermined high level. The control system according to this embodiment controls the safe injection flow rate depending on the pressurizer water level value if the water level of the steam generator does not correspond to the high level even by the high water level detecting unit 90, and the water level of the steam generator is When it is determined that the water level is high by the high water level detecting unit 90, a process of comparing and determining the water level of the pressurizer is performed in order to prevent a rapid increase in the water level of the steam generator.

The signal conversion unit 30 controls the safe injection flow rate by generating and transmitting different conversion signals depending on whether the high water level detection unit 90 of the steam generator is present.

Specifically, when the water level of the steam generator does not reach a predetermined high level, a switching signal based on the pressurizer water level signal is generated and transmitted. When the water level of the steam generator is not the high level, the safety injection flow rate control valve 60 can be controlled depending on the pressurizer water level value. 60) is controlled to open more. The signal conversion unit 30 generating a switching signal depending on only the pressurizer water level signal is a process of converting the form of the pressurizer water level signal so that the main controller 40 can generate an appropriate valve control signal.

On the other hand, if the water level of the steam generator is determined to be a predetermined high level by the high water level detecting unit 90, the conversion including the relative water level information obtained by comparing the water level value of the pressurizer with the water level value of the steam generator Generate and transmit signals. According to the present embodiment, the signal conversion unit 30 converts the steam generator water level value into a predetermined form, as in the embodiment of FIG. 1 , in order to compare the pressurizer water level value with the steam generator water level value. Of course, the pressurizer water level value may be converted into a predetermined form and compared with the steam generator water level value.

According to this embodiment, the conversion signal generated by the signal conversion unit 30 in a situation where the water level of the steam generator is a high water level is derived based on the difference value of the converted steam generator water level value from the pressurizer water level value do. When the difference value has a negative (-) value, it is determined that the water level value of the steam generator is relatively high compared to the water level value of the pressurizer. In this case, the supplied safety injection flow rate is controlled in a decreasing direction. On the other hand, when the water level of the pressurizer is lower than a predetermined value, the safe injection flow rate is controlled in an increasing direction. For example, when the water level of the pressurizer is too low, even if the water level of the steam generator is high, the safety injection flow rate may be controlled in a direction to increase.

As such, the signal conversion unit 30 according to the present embodiment generates and transmits a conversion signal based on only the pressurizer water level signal, depending on whether the water level of the steam generator is a high level by the high water level detecting unit 90 . Alternatively, a process of generating and transmitting a conversion signal obtained by comparing and determining the pressurizer water level value and the steam generator water level value is selectively performed.

The main controller 40 receives the switching signal to generate and transmit a valve control signal for controlling the opening degree of the safety injection flow rate control valve 60 for adjusting the safe injection flow rate. For example, when the water level of the steam generator is high, and the switching signal is a negative value, the main controller 40 generates a valve control signal to close the safety injection flow rate control valve 60 and injects safety Allow the injection flow to be reduced. And, according to this embodiment, the main controller 40 is used as a PI controller, similarly to the embodiment of FIG. 1 .

The valve controller 50 opens and closes the safety injection flow rate control valve 60 by receiving the valve control signal transmitted from the main controller 40 . When the heat pipe is broken and the water level of the steam generator rises to a relatively higher level than the water level of the pressurizer, the main controller 40 generates a valve control signal to close the safety injection flow rate control valve 60, so it is received The valve controller 50 controls the valve in a direction to reduce the injected safety injection flow rate by operating the safety injection flow rate control valve 60 in a closing direction.

The safety injection control system for preventing the high water level of the steam generator according to the present embodiment includes a water level information storage unit 70 for storing the water level value of the steam generator. The main controller 40, based on the water level information of the steam generator stored in the water level information storage unit 70, when the rate at which the water level of the steam generator increases, the safety injection in proportion to the rate of increase The valve control signal is generated so that the flow control valve 60 is closed.

As such, by allowing the safety injection flow rate control valve 60 to close rapidly in proportion to the speed of increasing the water level of the steam generator, the safety injection flow rate control valve 60 closes rapidly in proportion to the speed at which the water level of the steam generator increases. It is possible to solve the problem of causing the full water level of the steam generator due to the late operator intervention.

As such, according to the embodiments of the present invention, when the heat pipe of the steam generator is broken, the high level of the steam generator due to excessive safety injection is prevented, thereby contributing to the improvement of the safety of the nuclear power plant.

In addition, according to the embodiments of the present invention, since the safe injection flow rate is adjusted by comparing and judging the water level of the pressurizer and the water level of the steam generator, it is also active in the event of a decrease in the water level of the pressurizer due to a decrease in the stock amount of the reactor coolant system, such as a coolant loss accident. provides a coping effect.

In the above, the present invention has been described in detail with respect to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications may be provided within the scope of the present invention.

10... Pressurizer water level transmission unit 20... Steam generator water level transmission unit
30... Signal converter 40... Master controller
50... Valve controller 60... Safety injection flow control valve
70... Water level information storage unit 80... Pressurizer water level signal conversion unit
90... high water level detection unit

Claims (6)

a pressurizer water level transmission unit for transmitting the water level value of the pressurizer;
Steam generator water level transmission unit for transmitting the water level value of the steam generator;
a signal conversion unit for receiving the pressurizer water level value and the steam generator water level value, and generating and transmitting a conversion signal including relative water level information obtained by comparing and determining the pressurizer water level value and the steam generator water level value;
a master controller that receives the switching signal and generates and transmits a valve control signal for controlling an opening degree of a safety injection flow rate control valve for controlling a safe injection flow rate;
A safety injection control system for preventing high water level in a steam generator, comprising a; a valve controller receiving the valve control signal to open and close the safety injection flow rate control valve. According to claim 1,
and a water level information storage unit for storing the water level value of the steam generator,
The main controller, based on the water level information storage unit, when the rate at which the water level of the steam generator increases, generates the valve control signal to close the valve in proportion to the rate of increase. Safe injection control system to prevent high water level. According to claim 1,
The steam generator water level value is converted into a predetermined form for comparison with the pressurizer water level value,
The switch signal is derived by the difference value of the converted steam generator water level value from the pressurizer water level value, and when the difference value is a negative (-) value, it is determined that the water level of the steam generator is relatively high,
The main controller generates a valve control signal to close the valve, and a safety injection control system for preventing high water level in the steam generator, characterized in that it reduces the safety injection flow rate. a pressurizer water level transmission unit for transmitting the water level value of the pressurizer;
a pressurizer water level signal conversion unit for generating and transmitting a pressurizer water level signal including relative pressurizer water level information by comparing the pressurizer water level value with a predetermined pressurizer water level setting value;
Steam generator water level transmission unit for transmitting the water level value of the steam generator;
a high water level detecting unit for detecting whether the water level of the steam generator is a high level;
1) when the water level of the steam generator does not reach a predetermined high level, a switching signal based on the pressurizer water level signal is generated and transmitted, or 2) the water level of the steam generator is set to a predetermined high level by the high level detection unit When it is determined, a signal conversion unit for selectively generating and transmitting a conversion signal including the relative water level information obtained by comparing the water level value of the pressurizer and the water level value of the steam generator;
a master controller for generating and transmitting a valve control signal for regulating the opening degree of a safety injection flow rate control valve for regulating the safe injection flow rate by receiving the singi switching signal;
A safety injection control system for preventing high water level in a steam generator, comprising a; a valve controller receiving the valve control signal to open and close the safety injection flow rate control valve. 5. The method of claim 4,
and a water level information storage unit for storing the water level value of the steam generator,
The main controller, based on the water level information storage unit, when the rate at which the water level of the steam generator increases, generates the valve control signal to close the valve in proportion to the rate of increase. Safe injection control system to prevent high water level. 5. The method of claim 4,
When the signal conversion unit generates a switch signal in a situation where the water level of the steam generator is a high level, the steam generator water level value is converted into a predetermined form for comparison with the pressurizer water level value,
The switch signal is derived by the difference value of the converted steam generator water level value from the pressurizer water level value, and when the difference value is a negative (-) value, it is determined that the water level of the steam generator is relatively high,
The main controller generates a valve control signal to close the valve, and a safety injection control system for preventing high water level in the steam generator, characterized in that it reduces the safety injection flow rate.

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