JP2012003310A - Plant monitoring device and plant monitoring system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a plant monitoring device and a plant monitoring system which can automatically reflect data changes to other plant monitoring devices.SOLUTION: A plant monitoring device 1 of an embodiment comprises: a first database DB1 for storing definition information of a first format; a conversion means 102b for converting image data composed of a plurality of objects which are described in a second format different from the first format into image data 102B described in the first format by referring to the first database; and a distribution means 103b for distributing the image data described in the first format.

Description

  Embodiments related to the present invention relate to a plant monitoring apparatus and a plant monitoring system.

  A plant monitoring system used for monitoring a large-scale plant, for example, a nuclear power plant, usually includes a plurality of plant monitoring apparatuses that are different systems. Each plant monitoring device includes display means for displaying a system diagram for monitoring the state of the plant and input means for changing the system diagram (for example, see Patent Document 1).

JP 2005-3911 A

  However, since each plant monitoring device is a different system, data for displaying a system diagram and the like (hereinafter referred to as screen data) are also described in different formats. For this reason, when the screen data is changed in a certain plant monitoring device, the user needs to change the screen data in order to reflect the change in other plant monitoring devices.

  Changing the screen data of all plant monitoring devices requires a huge amount of work, and inevitably increases human errors (for example, data input errors). Moreover, the time when the change of the screen data is reflected is different for each plant monitoring device, and as a result, the screen data is different between the plant monitoring devices.

  The present embodiment has been made to solve such conventional problems, and an object thereof is to provide a plant monitoring apparatus and a plant monitoring system that can automatically reflect data changes in other plant monitoring apparatuses.

  The plant monitoring apparatus according to the embodiment is described in a first database in which definition information of the first format is stored, and in a second format different from the first format with reference to the first database. Conversion means for converting screen data composed of a plurality of objects into screen data described in the first format, and distribution means for distributing the screen data described in the first format.

  The plant monitoring system according to the embodiment is described in a first database in which definition information of the first format is stored, and in a second format different from the first format with reference to the first database. A conversion unit that converts screen data composed of a plurality of objects into screen data described in a first format; and a distribution unit that distributes screen data described in a first format. Plant monitoring device, a third database in which screen data described in the first format is stored, receiving means for receiving screen data distributed from the first plant monitoring device, and received screen data And updating means for updating the screen data stored in the third database using the second plant monitoring device And it comprises a.

  According to the present invention, it is possible to reflect the change contents of the screen accompanying the change of the plant to each system, and it is possible to prevent data inconsistency between systems such as erroneous display due to a human error.

It is a block diagram of the plant monitoring system which concerns on embodiment. It is a block diagram of the plant monitoring apparatus which concerns on embodiment. It is a flowchart which shows operation | movement of the plant monitoring system which concerns on embodiment.

Hereinafter, this embodiment will be described in detail with reference to the drawings.
(Embodiment)

Hereinafter, embodiments will be described in detail with reference to the drawings.
In this embodiment, a nuclear power plant will be described as an example of a monitoring target plant.

  FIG. 1 is a configuration diagram of a plant monitoring system 1 according to this embodiment. The plant monitoring system 1 includes a nuclear power plant 10, a process control device 20, a process data input device 30, a network 40, and plant monitoring devices 51 to 53.

  The process data input device 30 periodically acquires data (process data) indicating the state of the nuclear power plant 10 and inputs the data to the plant monitoring devices 51 to 53. The process data are measurement data values such as the rotational speed and temperature of various devices (for example, a pump and a turbine) provided in the nuclear power plant 10.

  The plant monitoring device 51 processes the process data input from the display means 51A for displaying the system diagram of the nuclear power plant 10, the input means 51B for accepting user input instructions, and the process data input device 30, and displays the display means 51A. And an apparatus main body 51C that converts the instruction received by the input means 51B into an instruction signal and inputs the instruction signal to the process control apparatus 20.

  The plant monitoring device 52 processes the process data input from the display means 52A for displaying the system diagram of the nuclear power plant 10, the input means 52B for accepting a user input instruction, and the process data input device 30, and the display means 52A. And an apparatus body 52C that converts the instruction received by the input means 52B into an instruction signal and inputs the instruction signal to the process control apparatus 20.

  The plant monitoring device 53 processes the process data input from the display means 53A for displaying the system diagram of the nuclear power plant 10, the input means 53B for accepting a user input instruction, and the process data input device 30, and displays the display means 53A. And an apparatus main body 53C that converts the instruction received by the input means 53B into an instruction signal and inputs the instruction signal to the process control apparatus 20.

  The plant monitoring devices 51 to 53 are different systems (for example, a monitoring system, a control system, etc.), and handled data formats (formats) are also different from each other. For this reason, the screen data for displaying the system diagram on the display means 51A to 53A is also described in different formats.

  The process control device 20 controls the state of the nuclear power plant 10 based on instruction signals input from the plant monitoring devices 51 to 53. Specifically, the rotational speed, temperature, and the like of various devices (for example, pumps and turbines) provided in the nuclear power plant 10 are controlled based on instruction signals from the plant monitoring devices 51 to 53.

  The network 40 connects the process control device 20, the process data input device 30, the network 40, and the plant monitoring devices 51 to 53 to enable transmission / reception of process data, instruction signals, and the like. The network 40 is usually wired, but may be wireless.

  FIG. 2 is a functional configuration diagram included in the apparatus main bodies 51C to 53C of the plant monitoring apparatuses 51 to 53. Hereinafter, the functional configuration of the apparatus main bodies 51C to 53C will be described in detail with reference to FIG. Note that these functions are realized by hardware included in each of the apparatus main bodies 51C to 53C. Specifically, each of the apparatus main bodies 51C to 53C includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a HDD (Hard Disk Drive), and the like (not shown). The functions described below are realized by loading a program recorded in the HDD into the RAM and executing it.

(Device main body 51C)
The apparatus main body 51C of the plant monitoring apparatus 51 includes a drawing support unit 101, a screen data generation unit 102, and a screen data management unit 103.

  When the user operates the input unit 51B to instruct to change the screen data in order to change the system diagram displayed on the display unit 51A, the instruction signal received by the input unit 51B is input to the drawing support unit 101. The

  The drawing support unit 101 generates drawing data 101A composed of a plurality of objects such as lines, rectangles, circles, and colors based on the input instruction signal. In the plant monitoring apparatus 51, a system diagram of the plant is displayed on the display means 51A based on the drawing data 101A.

  The screen data generation unit 102 includes attribute decomposition means 102a, basic screen data generation means 102b, screen data generation means 102c, and DB (database) 1 to DB3.

  The attribute decomposing unit 102a (decomposing unit) generates the decomposing attribute data 102A by decomposing the drawing data 101A generated by the drawing supporting unit 101 for each object attribute (for example, circle, rectangle, line, color, etc.). To do. By decomposing the drawing data 101A according to the attributes, each object constituting the drawing data 101A can be managed individually.

  DB1 (first database) stores definition information of formats used in the systems, that is, the plant monitoring devices 52 and 53, respectively. The basic screen data generation unit 102b (conversion unit) redefines the decomposition attribute data 102A generated by the attribute decomposition unit 102a in the formats used by the plant monitoring devices 52 and 53, with reference to DB1. Basic screen data 102B is generated. The basic screen data 102B is generated for each of the plant monitoring devices 52 and 53.

  By redefining the format suitable for each system, it is possible to reflect the changes in the screen accompanying the change of the plant in each system. Furthermore, it is possible to prevent data inconsistency between systems such as erroneous display due to human error (for example, input error).

  DB2 (second database) stores an object for realizing a screen function unique to each system, that is, the plant monitoring devices 52 and 53. For example, an object such as a link button from one system diagram to another statistical diagram, an operation button object for turning on / off the operation of an arbitrary device (for example, a pump), etc., to realize the above screen function It corresponds to the object.

  The screen data generation unit 102c (addition unit) refers to DB2, and the basic screen data 102B generated by the basic screen data generation unit 102b is unique to each system, that is, the plant monitoring devices 52 and 53, respectively. The screen data 102C to which an object for realizing the function is added is generated. The screen data 102C is generated for each of the plant monitoring devices 52 and 53.

  As a result, screens that reflect system-specific screen operations such as screen expansion functions can be automatically generated, making it unnecessary to manually create screens manually for each system, thereby reducing maintenance and resource management costs. Become.

  The screen data management unit 103 includes screen data management means 103a (storage means) and screen data distribution means (distribution means) 103b. The screen data management means 103a attaches a revision number (revision number) to the screen data 102C generated by the screen data generation means 102c, and stores it in the DB 3 as screen master data.

  The screen data distribution unit 103b acquires the latest revision number screen data 102C from the DB 3 and distributes it to the corresponding system (plant monitoring device).

(Device main body 52C, 53C)
The device main body 52C of the plant monitoring device 52 includes screen data updating means 201a (receiving means and updating means), screen registration means 201b, DB4 and DB5. The device main body 53C of the plant monitoring device 53 includes screen data update means 202a, screen registration means 202b, DB6 and DB7.

  The screen data update unit 202a, screen registration unit 202b, DB6, and DB7 of the device main body 53C correspond to the screen data update unit 201a, screen registration unit 201b, DB4, and DB5 of the device main body 52C, respectively, and have the same functions and operations. Therefore, here, the configuration of the apparatus main body 52C will be described, and the description of the configuration of the apparatus main body 53C will be omitted.

  When the latest screen data is distributed from the screen data distribution unit 103b of the apparatus main body 51C, the screen data update unit 201a updates the screen data stored in the DB 5 (third database).

  As a result, drawing information composed of data formats and attributes that can be handled by the display means 52A of the plant monitoring device 52 is provided, and at the same time the plant change content is reflected in the system (plant monitoring device 52) having a different environment. Sex can be secured.

  The screen registration unit 201b registers management information such as the ID, name, and revision number of the screen data updated by the screen data update unit 201a in the DB 5.

FIG. 3 is a flowchart showing the operation of the plant monitoring system 1 according to the embodiment.
Hereinafter, the operation of the plant monitoring system 1 according to the embodiment will be described with reference to FIG. 3.
First, when the user operates the input unit 51B to instruct the change of the screen data in order to change the system diagram displayed on the display unit 51A, the instruction signal received by the input unit 51B is changed to the drawing support unit 101. The system diagram is changed (step S101).

  The drawing support unit 101 generates drawing data 101A composed of a plurality of objects such as lines, rectangles, circles, and colors based on the input instruction signal (step S102).

  The attribute decomposing means 102a decomposes the drawing data 101A generated by the drawing support unit 101 for each object attribute (for example, circle, rectangle, line, color, etc.) to generate decomposition attribute data 102A (step S103). .

  The basic screen data generation unit 102b refers to DB1, and the basic screen data 102B obtained by redefining the decomposition attribute data 102A generated by the attribute decomposition unit 102a into the formats used by the plant monitoring devices 52 and 53, respectively. Is generated (step S104).

  The screen data generation unit 102c refers to DB2 and adds unique attributes used in each system, that is, the plant monitoring devices 52 and 53, to the basic screen data 102B generated by the basic screen data generation unit 102b. The screen data 102C thus generated is generated (step S105).

  The screen data management unit 103a adds a revision number (revision number) to the screen data 102C generated by the screen data generation unit 102c, and stores it in the DB 3 as the screen master data 103A (step S106).

  The screen data distribution unit 103b acquires the latest revision number screen data 102C from the DB 3 and distributes it to the corresponding system (plant monitoring device) (step S107).

(Device main body 52C, 53C)
When the latest screen data is distributed from the screen data distribution unit 103b of the apparatus main body 51C, the screen data update unit 201a updates the screen data stored in the DB 5 (step S108).

  The screen registration unit 201b registers management information such as the ID, name, and revision number of the screen data updated by the screen data update unit 201a in the DB 5 (step S109), and ends the operation.

  As described above, when the screen data of the plant monitoring device 51 is changed, the plant monitoring system 1 according to the embodiment decomposes the changed screen data into each attribute, and then other systems (plant monitoring devices 52 and 53). The data is converted into data suitable for the format of the screen data used in (1) and distributed to the plant monitoring devices 52 and 53. In the plant monitoring devices 52 and 53, the screen data stored in the DB is updated using the screen data distributed from the plant monitoring device 51.

  For this reason, the change contents of the screen data accompanying the change of the plant can be reflected in each system. Furthermore, it is possible to prevent data inconsistency between systems such as erroneous display due to human error (for example, input error). In addition, a screen reflecting a screen operation unique to the system such as a screen expansion function can be automatically generated, and an original screen creation operation by manual operation for each system is not required, and maintenance and resource management costs can be suppressed.

(Other embodiments)
In the above embodiment, the nuclear power plant has been described as an example. However, the present invention is not limited to the nuclear power plant, and can be applied to other plants such as a thermal power plant, a hydroelectric power plant, a chemical plant, and the like. Further, the system (plant monitoring device) may be provided with a plurality (two or more), and is not limited to three.

  Furthermore, in the said embodiment, although the plant monitoring apparatus 51 changes screen data, such as a system diagram, it converts into the format used with another system, and distributes to the plant monitoring apparatuses 52 and 53, The screen data such as a system diagram may be changed by the monitoring device 52 or the plant monitoring device 53, converted into a format used in another system, and distributed to another system.

  DESCRIPTION OF SYMBOLS 1 ... Plant monitoring system, 10 ... Nuclear power plant, 20 ... Process control apparatus, 30 ... Process data input device, 40 ... Network, 51-53 ... Plant monitoring device, 51A-53A ... Display means, 51B-53B ... Input means , 51C to 53C ... device main body, 101 ... drawing support unit, 102 ... screen data generation unit, 102a ... attribute decomposition means (decomposition means), 102b ... basic screen data generation means (conversion means), 102c ... screen data generation means ( Adding means), 103a... Screen data managing means (storage means), 103b... Screen data distributing means (distributing means), 201a, 202a... Screen data updating means (receiving means, updating means), 201b, 202b.

Claims (5)

A first database storing definition information of a first format;
Referring to the first database, screen data composed of a plurality of objects described in a second format different from the first format is converted into screen data described in the first format. Conversion means to
Delivery means for delivering screen data described in the first format;
A plant monitoring device comprising: Further comprising a decomposing means for decomposing the screen data for each attribute of the object;
The plant monitoring apparatus according to claim 1, wherein the conversion unit re-describes the disassembled object in the first format. A second database in which objects for realizing functions specific to the first format are stored;
Adding means for adding the object to the first format to the screen data converted to the first format by the converting means with reference to the second database;
The plant monitoring apparatus according to claim 1, further comprising:   The plant monitoring apparatus according to any one of claims 1 to 3, further comprising storage means for adding management information to the converted screen data for storage. A first database in which definition information of the first format is stored, and a plurality of objects described in a second format different from the first format with reference to the first database A first plant monitoring apparatus comprising: conversion means for converting screen data into screen data described in the first format; and distribution means for distributing screen data described in the first format; ,
A third database in which screen data described in the first format is stored;
Receiving means for receiving the screen data distributed from the first plant monitoring device; and updating means for updating the screen data stored in the third database using the received screen data; A second plant monitoring device comprising:
A plant monitoring system comprising:

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