KR101140698B1 - System and method for managing potential single point vulnerabilities - Google Patents

Abstract

PURPOSE: A system and a method for managing potential single point vulnerabilities is provided to systematically manage a vulnerable device by estimating and analyzing a ripple effect due to the malfunction of a system apparatus. CONSTITUTION: A sensor(110) senses the malfunction of a specific apparatus. An input unit(120) receives information from the sensor and input operation commands. A memory unit(130) stores atomic power plant apparatus information, etc. An analysis unit(140) analyzes the significance of apparatuses. A display unit(150) displays the analyzed result of the analysis unit.

Description

Management system and method of potential generation stop equipment {{SYSTEM AND METHOD FOR MANAGING POTENTIAL SINGLE POINT VULNERABILITIES}

The present invention relates to a management system and method of the potential generation stop equipment, and more particularly, to identify, check and manage detailed vulnerable equipment that can stop a nuclear power plant. The present invention relates to a management system and a method thereof.

Until now, domestic nuclear power plants have taken the strategy of performing intensive monitoring and improvement by checking the equipment's operation experience and the system knowledge of the personnel who can stop the power plant by single failure during full power operation. However, the causes of recent power plant outages are complex, which cannot be prevented by considering only a single failure, such as equipment failure or human error of operators or maintenance personnel under specific system operating conditions, or power failure due to malfunction or failure of additional equipment. The aspect is showing.

The present invention belongs to the field of power plant reliability evaluation, and in the prior art, there was no system for identifying potential power generation-induced equipment before maintenance or inspection of the power plant based on the reliability-based logical quantitative evaluation results, and the state of the inspection target system according to the retention procedure. Only confirmation and prechecks were performed.

In addition, in the past, during the inspection during normal operation such as maintenance and testing, attention was focused only on a few devices related to the test because a qualitative pre-assessment process such as a drawing and a review of past history of similar power generation was reviewed. Furthermore, there was a problem that the functional importance of the power plant equipment was determined based on the experience of the power plant grid personnel, resulting in a difference in the functional importance of the same grid equipment despite the same type of plant.

The present invention has been devised in view of the above problems, and an object of the present invention is to analyze potential generation stop equipment, generation stop propagation effect, and importance of equipment by using tree diagram and stop logic diagram. The present invention provides a management system and method for causing an induced device.

The present invention for achieving the technical problem, the sensing unit for detecting the failure of the nuclear power plant-specific devices located around the nuclear power plant components; An input unit for receiving power generation stop equipment information from the detection unit and receiving a work order; A memory unit for storing nuclear power plant equipment information, tree tree diagrams, and static logic diagrams; An analysis unit for analyzing a potential power generation stop device, analyzing a power generation stop effect, and analyzing the importance of the potential power generation stop device; And a display unit for displaying an analysis result of the analysis unit. Characterized in that it comprises a.

Preferably, the memory unit may include a device DB for storing device information, a tree tree diagram DB for storing a tree tree diagram, and a stationary logic diagram DB for storing a stationary logic diagram.

Also preferably, the analysis unit, a potential power generation stop equipment analysis module for analyzing the potential power generation stop equipment; A power generation stop effect analysis module for analyzing the power generation stop effect according to the failure of the analysis target device; And an importance analysis module for analyzing the importance of the components of the nuclear power plant; Characterized in that it comprises a.

On the other hand, in the management method of the potential power generation-induced equipment, (a) the process of detecting the failure of the component of the nuclear power plant; (b) the input unit receiving a work order; (c) the analysis unit analyzes the potential power generation-induced equipment, the effect of the power plant shutdown and the importance of the components of the nuclear power plant; And (d) displaying the analysis result of the display unit; Characterized in that it comprises a.

Also preferably, the process (c) may include: (c-1) analyzing the potential generation stop equipment by the potential generation stop equipment analysis module; (c-2) analyzing, by the power generation stop effect analysis module, the power generation stop effect according to the failure of the analysis target device using the stop logic explanatory diagram; And (c-3) the importance analysis module analyzing the importance of the system configuration device using a predetermined importance determination table; Characterized in that it comprises a.

Also preferably, the step (d) is characterized in that for displaying the list of power generation stop equipment, the list of potential power generation stop equipment.

And, preferably, the step (d), characterized in that the power generation stop risk, the work target device, the output reduction related system arrangement and output reduction level.

According to the present invention as described above, it is possible to identify potential generation stop equipment using the tree tree diagram, predict the ripple effect due to the failure of the system component through the stop logic explanatory diagram, by using the importance analysis module By assessing the importance of individual devices, it is possible to systematically manage vulnerable devices that can suddenly shut down a nuclear power plant.

1 is a block diagram of a management system of a potential power generation stop equipment according to an embodiment of the present invention.
2 is a configuration diagram of a memory unit according to an embodiment of the present invention.
Figure 3 is a plant tree tree according to an embodiment of the present invention.
Figure 4 is a schematic diagram of the stop logic according to an embodiment of the present invention.
5 is a block diagram of an analysis unit according to an embodiment of the present invention.
Figure 6 is a block diagram of the interrelationship between the main system and the auxiliary system according to an embodiment of the present invention.
7 is a display unit according to an embodiment of the present invention.
8 is a flowchart of a method of managing a potential power generation stoppage device according to an embodiment of the present invention.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. In the meantime, when it is determined that the detailed description of the known functions and configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, it should be noted that the detailed description is omitted.

For reference, Single Point Vulnerability (SPV) is a device that causes any one or more of a reactor shutdown, power generation stop or output derating due to its own single failure. Potential SPV is a device that temporarily becomes a power generation induction device due to a change in system arrangement (operation conditions) due to a failure or test of a facility that may occur during normal output operation.

Referring to Figures 1 to 8 with respect to the management system (hereinafter referred to as 'management system') 100 and the method of the potential power generation induced device according to the invention as follows.

As shown in FIG. 1, the management system 100 includes a sensing unit 110, an input unit 120, a memory unit 130, an analysis unit 140, and a display unit 150.

The detector 110 is located around the component 10 of the nuclear power plant, and detects device information such as device name, ID, and status when a specific device of the nuclear power plant is broken.

The input unit 120 receives a work order and device information.

As shown in FIG. 2, the memory unit 130 includes a device DB 131 storing nuclear power plant device information, a work order DB 133 for storing an existing work order and storing a new work order, and a system. The tree tree diagram DB 135, which stores the tree diagram, and the stop logic diagram DB 137, which stores the stop logic diagram.

In addition, the device DB 131 may store device information such as a name, state, importance, device failure rate, etc. of a device set in advance, and may be modified or added to device information received from the input unit 120.

In addition, the work order DB 133 stores a preset work order, receives a new work order from the input unit 120 and stores it.

In addition, the tree tree diagram DB 135, as shown in Figure 3, stores a tree tree diagram showing a potential power generation stop equipment associated with a particular device failure.

In addition, the stop logic explanatory diagram DB 137 stores a stop logic explanatory diagram showing devices associated with subsequent steps influencing power generation stop / output deceleration due to device failure between operations as shown in FIG. 4. do.

As shown in FIG. 5, the analysis unit 140 generates a potential power stop triggering device analysis module 141 for analyzing a potential power stop triggering device and a power generation for analyzing a subsequent power stop effect due to an analysis target device failure. The stop effect analysis module 143 includes an importance analysis module 145 for analyzing the importance of the potential generation stop equipment.

The potential generation stop equipment analysis module 141 may cause a power plant to stop by a failure of a specific device, using a system tree and [Equation 1] logically constructed a power plant equipment failure combination, the failure of the corresponding device Other equipment (picking equipment, its controllers, power supply equipment and cooling medium supply equipment) are considered as potential power outage-inducing equipment.

[A_i*B_i + A_i*(JB_i+EB_i+MB_i) + B_i*(JA_i+EA_i+MA_i) + (JA_i+EA_i+MA_i)*(JB_i+EB_i+MB_i)][Equation 1] Failure combination of power generation stop equipment =

(A _i * B _i + A _i * (JB _i + EB _i + MB _i ) + B _i * (JA _i + EA _i + MA _i ) + (JA _i + EA _i + MA _i ) * (JB _i + EB _i + MB _i )]

Where A is a periodic device necessary for normal operation of a power plant, B is a cost-effective device of a periodic device, JA is a device that provides control to the cycle, EA is a device that supplies power to the cycle, and MA is a coolant in the cycle. JB: equipment to provide control function to post-cost equipment, EB: equipment to supply power to post-cost equipment, MB: equipment to supply coolant (oil) to post-cost equipment.

For example, the judgment of potential generation stop equipment is A1 = 1 when a specific cycle (A1) failure occurs. Equation 1 is B ₁ + JB ₁ + EB ₁ + MB ₁ + B ₁ * (JA ₁ + EA ₁ + MA ₁ ) + (JA ₁ + EA ₁ + MA ₁ ) * (JB ₁ + EB ₁ + MB ₁ ). Therefore, the power generation stop equipment is B ₁ , JB ₁ , EB ₁ , MB ₁ .

FIG. 6 is a block diagram illustrating a relationship between a main system and an auxiliary system according to an embodiment of the present invention, in which a problem occurs in an entire motor driving pump associated with a single device auxiliary system.

When displaying the list of potential generation stop equipments, the operator may obtain a list of post-cost devices (or multi-channel devices) and their auxiliary system devices in a channel or a group of groups performing the same function, in addition to the device to be inspected. This will enable you to proactively identify potential risk factors that can cause plant outages.

The power generation stop effect analysis module 143 loads the stop logic explanatory diagram from the DB (137) associated with the failed device, and how the failure combination of the inspection target device and the potential power generation stop device affects the operation of the power plant. A stop logic explanatory diagram briefly indicating whether to reach a power station stop is transmitted to the display unit 150. Enter a comment in the main connection section of the fault logic diagram that relates to the fault combination to link this added comment to indicate what fault propagation process will lead to a plant shutdown. As a result, the inspector can work with the understanding that the maintenance / test work they perform can be linked to the equipment and cause plant shutdowns.

When the importance analysis module 145 performs a Boolean logic operation by linking a device failure rate to a tree tree diagram, a power generation risk value is derived as a result based on the input failure rate of the input device, and the result is affected by the power failure. By categorizing the importance (contribution) by each device, the quantitatively determines the devices to be concentrated and transmits them to the display unit 150.

The importance classification consists of three stages: facility class classification, importance class classification, operating frequency and operating environment classification. The equipment class (type) classification is classified as one of the specific equipment types for all the equipment of the power plant in order to apply the correct preventive maintenance criteria. In addition, the importance class classification classifies the devices corresponding to the management target according to the importance level and classifies all the devices of the power plant into four classes according to the critical class classification criteria (Critical A, Critical B, Minor, No Impact). In addition, the driving frequency and the driving environment classification classify the driving frequency and the driving environment according to the presented criteria for the equipment whose importance classification and facility class classification work is completed. The driving frequency is classified as High or Low, and the driving environment is classified as Severe or Mild.

Class A and Critical B (critical A, Critical B) are those in which the failure of the equipment is closely related to the safety of the reactor and the operation of the power plant. Although not followed, it is a device that is worth managing in terms of indirectly affecting plant safety and reliability, industrial safety, or performing cost-effective preventive maintenance, and a class X (No Impact) is any device not classified as Critical or Minor. It has little or no function on safety, plant output and economics. The equipment classified as class X is applied as a RTF (Run-to-Failure) device in the preventive maintenance program, and does not perform the preventive maintenance but performs only the trouble maintenance work in case of failure.

The importance analysis module 145 has a high FV (Fussel-Vesely) importance and device characteristics in terms of device performance influencing the total annual power generation stop frequency value according to the characteristics of the logical combination analysis result related to the magnitude of the failure rate value of the device. We use RAW (Risk Achievement Worth) importance comparison to identify equipment that has reliability but greatly affects power failure in case of failure. The results of the importance evaluation for each device are finally used to quantitatively determine the importance of the device considering the characteristics of the system (see Table 1).

[Table 1] Determination of quantitative importance of instrument

The results of the materiality analysis are used as input data when determining the functional importance of each device.In accordance with the results, the device is classified into high-performance devices from the viewpoint of performance and high-powered devices from the standpoint of power generation risk. Determine the functional importance of (see Table 2) and transmit the result to the display unit 150 of the device DB (131).

[Table 2] Determination of functional importance based on quantitative importance results

As shown in FIG. 7, the display unit 150 includes a list of generation stop equipment, a stop risk, a work target device, a stop logic explanation diagram, a tree tree diagram, a system array related to output reduction, an output reduction level, and a potential generation stop generation. Display the device list.

The power generation stop triggering device list represents a list of devices that cause power generation stop or output reduction when a single fault occurs according to the tree tree diagram, and the stop risk brings the failure rate of the device DB 131 into the tree tree tree to bring out the Boolean logic. The calculation is based on the failure rate of the input device information. The work target device represents a work target device associated with a work order detected by the sensing unit 110 or received from the input unit 120, and the stop logic explanatory diagram illustrates a stop logic explanatory diagram associated with the power generation stoppage inducing device. The stop logic explanation diagram is retrieved from the DB 137 and displayed, and the output arrangement related system arrangement indicates the operating state of the system cycle machine related to the power generation stoppage equipment using the system tree diagram. The potential generation stop equipment list is displayed, and the potential generation stop equipment list displays those classified as potential generation stop equipment by the analysis result of the potential generation stop equipment analysis module 141 of the analysis unit 140. do.

Hereinafter, a description will be given of a method for managing a potential power generation-induced device having the above configuration.

8 is a flowchart illustrating a method of managing a potential power generation stop equipment according to an embodiment of the present invention. In the method of managing a potential power generation stop equipment as shown, the sensing unit generates power generation stop in a component of a nuclear power plant. Detecting the device (S100), the input unit receives a work order (S200), the analysis unit potential power generation stop device, the power generation stop effect and the process of analyzing the importance of the components of the nuclear power plant and the display unit And displaying the result of the analysis (S400).

Specifically, the process of S100 to S400, the detection unit 110 of the management system detects a failure state of the component 10 of the nuclear power plant (S100), the input unit 120 receives a work order and the work The order is stored in the work order DB 133 of the memory unit 130 (S200).

In the step S300, the potential generation stop equipment analysis module analyzes the potential generation stop equipment using the tree diagram (S310), and the generation stop effect analysis module analyzes the generation stop effect using the stop logic explanatory diagram. Step (S320) and the importance analysis module consists of a step of analyzing the importance (S330) using a predetermined importance determination chart of the potential generation stop equipment. The potential generation stop generating device analysis module 141 of the management system loads the device information from the device DB 131 of the memory unit 130 and the tree tree drawing from the tree tree drawing DB 135, thereby causing a potential power stop generating. The device is analyzed (S310). The generation stop effect analysis module 143 of the management system retrieves the stop logic explanatory diagram from the stop logic explanatory diagram DB 137 and analyzes the ripple effect related to the generation stop or output deceleration when the corresponding device causes a failure. (S320). The importance analysis module of the management system evaluates the importance of the nuclear power plant component 10 (S330). The display unit 140 displays the result analyzed by the analysis unit (S400).

In the S400 process, the analysis results include the above-described generation stop triggering device list, stop risk, work target device, stop logic explanatory diagram, tree tree diagram, output sensing related system arrangement, output reduction level, and potential power stop triggering device list. Say.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be appreciated by those skilled in the art that numerous changes and modifications may be made without departing from the invention. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

10: component of nuclear power plant 100: management system
110: detection unit 120: input unit
130: memory unit 131: device DB
133: work order DB 135: tree tree diagram DB
137: static logic diagram DB 140: analysis unit
141: Analysis module of potential power generation stop equipment
143: power failure effect analysis module 145: importance analysis module
150: display unit

Claims (7)

A detector configured to be positioned around a nuclear power plant component to detect a failure of a specific nuclear power plant;
An input unit for receiving power generation stop equipment information from the detection unit and receiving a work order;
A memory unit for storing nuclear power plant equipment information, tree tree diagrams, and static logic diagrams;
An analysis unit for analyzing a potential power generation stop device, analyzing a power generation stop effect, and analyzing the importance of the potential power generation stop device; And
A display unit which displays an analysis result of the analysis unit; The management system of the potential power generation-induced equipment comprising a.
The method of claim 1,
The memory unit,
12. A management system for a potential power failure-inducing device, comprising: a device DB for storing device information, a tree tree diagram for storing tree tree diagrams, and a stop logic diagram for storing stationary logic diagrams.
The method of claim 1,
The analysis unit,
A potential generation stop equipment analysis module for analyzing potential generation stop equipment;
A power generation stop effect analysis module for analyzing the power generation stop effect according to the failure of the analysis target device; And
Importance analysis module for analyzing the importance of the nuclear power plant component; A management system for a potential power outage-inducing device comprising a.
In the management method of potential generation stop equipment,
(a) the sensing unit detects a failure of the components of the nuclear power plant;
(b) the input unit receiving a work order;
(c) the analysis unit analyzes the potential power generation-induced equipment, the effect of the power plant shutdown and the importance of the components of the nuclear power plant; And
(d) displaying the analysis result of the display unit; Method for managing a potential power generation-induced equipment comprising a.
The method of claim 4, wherein
The step (c)
(c-1) analyzing the potential generation stop equipment using the tree diagram in the potential generation stop equipment analysis module;
(c-2) analyzing, by the power generation stop effect analysis module, the power generation stop effect according to the failure of the analysis target device using the stop logic explanatory diagram; And
(c-3) the importance analysis module analyzing the importance of the system configuration device using a predetermined importance determination table; Method of management of the potential power outage-inducing device comprising a.
The method of claim 4, wherein
(D) process,
A method of managing a potential generation stop equipment, characterized by displaying a list of generation stop equipment and a list of potential generation stop equipment.
The method of claim 4, wherein
(D) process,
A method for managing a potential power failure-inducing device, characterized by displaying the power generation stop risk, the target equipment, the system arrangement related to the output reduction, and the output reduction level.

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