JP2009301417A - Plant monitoring control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To facilitate system maintenance while preventing system configuration definition error in an engineering server, in a plant monitoring control system. <P>SOLUTION: The plant monitoring control system includes: a storage device 4M provided with a system configuration definition table wherein the connection information of a PIO device 3 corresponding to a controller 2 is registered; and the engineering server 4 provided with an automatic system configuration information generating function 4-3 for gathering the actual connection information of the controller and the actual connection information of the PIO device corresponding to the controller through a network, determining whether or not the actual connection information of the controller and the actual connection information of the PIO device corresponding to the controller that are gathered and the connection information of the controller and the connection information of the PIO device corresponding to the controller registered in the system configuration definition table are different, and updating the system configuration definition table to the actual connection information of the controller and the actual connection information of the PIO device corresponding to the controller when they are different. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention comprises a control device that transmits and receives plant control equipment and monitoring control signals via a PIO device on a network, and an operator star that is connected to the control device via a network and performs monitoring control via the control device. The present invention relates to a plant monitoring control system.

  FIG. 11 is a diagram showing a data update flow in a conventional plant monitoring apparatus, which is composed of a service requesting side and a service providing side, and the service providing side returns a response to a request from the service requesting side. . There can be multiple service providers.

  Next, the operation will be described.

  On the service request side, a policy to be disclosed via the network and a range for searching for resources are set for devices (resources) connected to the own device (step ST2111). Next, a service condition to be requested is transmitted (step ST811). When the service providing side receives the requested service condition from the service requesting side, the service providing side determines whether or not the service providing side can provide the service condition, and returns a response if it matches (step ST812). The service request side receives a response from the service providing side (step ST813), resolves the device used by itself and generates a service session identifier (step ST814). Next, it is determined whether the generated service is valid (step ST2113). If the service is invalid, the resource disclosure policy is updated again (step ST2115), and the process of sending the requested service condition (step ST811) is re-executed. To do. If the service is valid, the service session identifier is distributed to the service provider (step ST815). When the service providing side receives the service session identifier from the service requesting side, it sets the mode in its own device (step ST816).

  The above process is applied to the specific manufacturing procedure of the plant monitoring device as follows.

  The service requesting side corresponds to the engineering server, and the service providing side corresponds to OPS. Here, when a new service (OPS addition, PIO addition / change, etc.) is performed, a resource disclosure policy is set on the service request side (added device) (step ST2111), and the required service condition is defined and transmitted. (Step ST811) is performed, and after confirming the response of the requested service (Step ST813), the used device is resolved (Step ST814).

  By the above procedure, system configuration information can be updated without losing data consistency when adding / removing / replacement of various devices such as OPS and PIO.

Japanese Unexamined Patent Publication No. 2004-199300 (FIG. 2 and its description)

In the conventional plant monitoring system, when expanding / removing / replacement of various devices such as OPS and PIO, it is necessary to manually correct and register all resource disclosure policies and search ranges such as address information and database. Without knowledge, I did not know which definition information should be modified.
Further, even an engineer with specialized knowledge manually changes various system configuration information, which may cause a definition error or work omission, and work efficiency is not good due to rework.

  The present invention has been made in view of the above-described circumstances, and includes a control device that transmits and receives plant control equipment and monitoring control signals via a PIO device on a network, and the control device that is connected to the control device via a network. An object of the present invention is to prevent a system configuration definition error in an engineering server and facilitate system maintenance in a plant monitoring control system having an operator station that performs monitoring control through an apparatus.

The plant monitoring and control system according to the present invention includes a control device that transmits and receives plant control equipment and monitoring control signals via a PIO device on a network, and is connected to the control device via a network and performs monitoring control via the control device. A plant monitoring and control system including an operator star to be connected to a network to which the control device and the operator star are connected, and connection information of the control device and connection of the PIO device corresponding to the control device The storage device having a system configuration definition table in which information is registered, and the control that collects and collects the actual connection information of the control device and the actual connection information of the PIO device corresponding to the control device via the network The actual connection information of the device and the actual PIO device corresponding to the control device And the connection information of the control device registered in the system configuration definition table and the connection information of the PIO device corresponding to the control device are different from each other. Is provided with an engineering server having a system configuration information automatic generation function unit that updates the system configuration definition table to the actual connection information of the control device and the actual connection information of the PIO device corresponding to the control device. is there.

  The present invention comprises a control device that transmits and receives plant control equipment and monitoring control signals via a PIO device on a network, and an operator star that is connected to the control device via a network and performs monitoring control via the control device. A plant monitoring and control system connected to a network to which the control device and the operator station are connected, wherein the connection information of the control device and the connection information of the PIO device corresponding to the control device are registered. A storage device having a configuration definition table, and the actual connection information of the control device that has collected and collected the actual connection information of the control device and the actual connection information of the PIO device corresponding to the control device via the network And the actual connection information of the PIO device corresponding to the control device and the system configuration It is determined whether or not the connection information of the control device registered in the definition table and the connection information of the PIO device corresponding to the control device are different. Since it has an engineering server having a system configuration information automatic generation function unit that updates the actual connection information of the control device and the actual connection information of the PIO device corresponding to the control device, the system is conventionally used by the engineering server. Caused by a system error in the controller when a definition error was made because the consistency was checked only when the controller was manually restarted after the configuration was manually generated and transferred to the controller. Although it took a long time to investigate, the present invention can prevent such a definition error and facilitate system maintenance. .

Embodiment 1 FIG.
Embodiment 1 of the present invention will be described below with reference to FIGS. FIG. 1 is a diagram showing an example of a system configuration, and FIG. 2 is a flowchart for explaining the operation of FIG.

  In FIG. 1, a plant monitoring control system includes a plurality of operator stations (hereinafter abbreviated as “OPS”) (OPS1, OPS2) 1-1, 1-2, and one or a plurality of control devices 2 (FIG. 1). Only one unit is shown), a PIO (Program I / O transfer) device 3, an engineering server 4, the OPS 1-1, 1-2, the control device 2, and the engineering server 4 are connected. An OPS network 5 and a PIO network 6 that connects the control device 2 and the PIO are configured.

The OPS 1-1 and 1-2 are devices that display the state of plant component equipment (not shown), which will be described later, based on data collected from the control device 2, and the plant configuration input by an operator. It is a device that sends a control command for the device to the control device 2.

The control device 2 is a device that controls the plant via the PIO device 3, for example, controls the plant constituent equipment based on the control command, and also controls the plant by a proper operation program stored in advance. Appropriate operation control of the plant component device is performed according to the state information of the component device. In addition, connection information of PIO devices actually connected to the own device (connection of PIO modules 3-1, 3-2, 3-3,. Information), state information of the plant component equipment, event information (abnormal operation, information on specific operation, etc.) and the like are stored in the internal storage device 2-1.

  The PIO device 3 incorporates a plurality of PIO modules (PIO1, PIO2, PIO3,... PIOn) 3-1, 3-2, 3-3,. Yes. The PIO modules (PIO1, PIO2, PIO3,..., PIOn) 3-1, 3-2, 3-3,..., 3-n are respectively control units (not shown) of the corresponding plant constituent devices. Various detectors (not shown) are connected via the PIO network 6, and are connected to the control device 2 via the PIO network 6. The PIO modules (PIO1, PIO2, PIO3,... PIOn) 3-1, 3-2, 3-3,..., 3-n correspond to the control commands and the control signals based on the proper operation programs. Transmit to the control unit of the plant component equipment via the PIO network 6, and transmit state detection signals detected by the various detectors of the plant component equipment to the control device 2 via the PIO network 6. To do.

The engineering server 4 is a server that manages system master data, and includes a system configuration definition table 4-1, a PIO type database 4-2, and a system configuration information automatic generation function unit 4-3.
The system configuration definition 4-1 and the PIO type database 4-2 are set in the storage device 4M.
The system configuration information automatic generation function unit 4-3 includes a system configuration information automatic generation program stored in a memory (not shown) and a CPU (not shown) that executes the program.

  The system configuration definition table 4-1 is, for example, a table storing definitions of the control devices included in the system and the connection information (PIO type, number of PIO points, etc.) of the PIOs connected to the control devices. It is.

  The PIO type database 4-2 refers to various system configuration information (for example, PI0 such as the number of IO points (input / output points) and range) for each PIO type of various PI0 devices and / or various PI0 modules that can be used in the monitoring control system. This is a database where the basic information of modules is defined and registered.

  Next, the operation will be described with reference to FIG.

  The PIO modules (PIO1, PIO2, PIO3,... PIOn) 3-1, 3-2, 3-3,... 3-n are connected to the PIO network 6 (step ST1), and the engineering server 4 To perform a “PIO network scan” operation (step ST2). When the PIO network scan operation is performed, the system configuration information automatic generation function unit 4-3 searches the PIO network 6 of each of the control devices 1 (2) and 2 (2), and the currently connected PIO device (PIO modules (PIO1, PIO2, PIO3,... PIOn) 3-1, 3, 2, 3-3,..., 3-n)) are acquired (step ST3).

  Next, the system configuration information automatic generation function unit 4-3 acquires the acquired current PIO modules (PIO1, PIO2, PIO3,... PIOn) 3-1, 3-2, 3-3,.・ Compare the connection state of the 3-n to the PIO network 6 with the definition data of the system configuration definition table 4-1 stored on the engineering server 4 and check whether there is any difference between them. (Step ST4). If there is a difference between the two, the system configuration information automatic generation function unit 4-3 refers to the PIO type database 4-2, and adds / deletes / replaces information on the PIO device (the PIO module (PIO1 , PIO2, PIO3,..., PIOn) 3-1, 3-2, 3-3,..., 3-n), and updates the data in the system configuration definition table 4-1 ( Step ST5).

  The system configuration definition table 4-1 includes PIO modules that are actually connected to the control devices 1 (2) and 2 (2), and the PIO type database 4-2 includes each PIO type (analog input). , Digital inputs, etc.) are defined and registered for the number of connections for each control device, and each control device 1 (2), 2 (2) uses the system configuration definition data for the number of PIO devices that it interfaces with. Create an address map. The PIO type database defines information for each PIO type, and defines basic information about the PIO module, such as the number of I / O points and input / output ranges.

  If there is no change in the control device 1 (2) (there is no difference between the two), the information of the next control device, for example, the control device 2 (2) is searched and the above processing is performed. The information of all the control devices is searched and the above-described processing is executed.

  As described above, according to the first embodiment of the present invention, the system configuration definition in the plant monitoring control system can be automatically generated in response to the addition / deletion / replacement of the PIO device in the plant.

  That is, as described above, for example, when a PIO device (PIO module) is additionally installed on the plant equipment side, the system configuration information automatic generation function unit 4-3 of the engineering server 4 defines the system configuration of the engineering server 4. Information of the additional PIO device (PIO module) is automatically added to the table 4-1 without artificially inputting to the plant equipment side.

  Similarly, for example, when a PIO device (PIO module) is deleted on the plant equipment side, the system configuration information automatic generation function unit 4-3 of the engineering server 4 uses the system configuration definition table 4-1 of the engineering server 4 to The information on the PIO device (PIO module) that is deleted on the plant equipment side is automatically deleted without any manual deletion.

  Similarly, for example, when a PIO device (PIO module) is replaced on the plant equipment side, the system configuration information automatic generation function unit 4-3 of the engineering server 4 uses the system configuration definition table 4- The information of the old PIO device (PIO module) before being replaced on the plant equipment side is automatically deleted without manual deletion and the new PIO device after being replaced on the plant equipment side ( PIO module) information is automatically registered in the system configuration definition table 4-1 without any manual input operation.

  In this way, when the PIO device (PIO module) is connected / removed / replaced on the plant equipment side, the plant monitoring control system side does not have to manually change the system configuration information. In response to the connection / removal / replacement of the PIO device (PIO module) on the plant equipment side, the system configuration information registered in the engineering server 4 on the plant monitoring control system side is automatically changed.

  In addition, even when the control device 2 is additionally connected / removed / replaced on the plant equipment side, information on the PIO device (PIO module) connected to the control device for the additional connection / removal / replacement via the PIO network In the same manner as described above, the system configuration information automatic generation function unit 4-3 associates the system configuration information in the system configuration definition table 4-1 of the engineering server 4 with the information on the control device for the additional connection / removal / replacement. Information is automatically added, deleted, or changed.

  In the first embodiment of the present invention, PIO configuration information on the PIO network is acquired by performing PIO network scan processing on the engineering server after connecting / removing / replacement of the PIO device to / from the PIO network. By comparing with the PIO configuration information on the engineering server, the PIO device addition / removal / replacement status is automatically detected, and the system configuration definition on the engineering server is automatically updated.

  Conventionally, after the system configuration definition was generated by the engineering server and transferred to the control device, consistency was checked only when the control device was restarted. However, since the system automatically recognizes according to the first embodiment of the present invention, such a definition error can be prevented and system maintenance is facilitated.

In the first embodiment, as described above, a control device that transmits and receives plant control devices and monitoring control signals via a PIO device on the network, and is connected to the control device via a network and monitored via the control device. A plant monitoring and control system including an operator station that performs control, and is connected to a network to which the controller and the operator station are connected, and connection information of the controller and the PIO device corresponding to the controller The storage device having the system configuration definition table in which the connection information of the device is registered, and the actual connection information of the control device and the actual connection information of the PIO device corresponding to the control device are collected and collected via the network. Actual connection information of the control device and actual connection information of the PIO device corresponding to the control device And whether the connection information of the control device registered in the system configuration definition table and the connection information of the PIO device corresponding to the control device are different. A plant monitoring and control system comprising an engineering server having a system configuration information automatic generation function unit that updates a configuration definition table to actual connection information of the control device and actual connection information of the PIO device corresponding to the control device. is there.
The system configuration definition table is a plant monitoring and control system in which the system configuration information automatic generation function unit is updated to information corresponding to the addition, removal, and replacement of the PIO modules that constitute the PIO device.

Embodiment 2. FIG.
A second embodiment of the present invention will be described below with reference to FIGS. FIG. 3 is a diagram showing another example of the system configuration, and FIG. 4 is a flowchart for explaining the operation of FIG. In the second embodiment, the contents used in the first embodiment include not only the system configuration information on the system configuration definition table 4-1, but also an application database 4-4 such as IO data and RAS information. However, the data and information on the application database 4-4 are automatically generated. The application database 4-4 is set in the storage device 4M.
Hereinafter, the operation of the second embodiment will be described with reference to FIG. 4 in association with each part of FIG. 3 only in the points different from the first embodiment.

  In the first embodiment described above, even if the system configuration definition for adding / deleting / replacing a PIO device (PIO) is updated, the IO database (IO points, input / output range, etc.) included in the PIO device, RAS There is a problem that application data such as information and alarm messages must be defined manually.

  The application database referred to here is a database in which one record exists for each PIO I / O point, and is proportional to the number of PIO modules.

  In the second embodiment, as illustrated in FIG. 4, the system configuration information automatic generation function unit 4-3 updates the system configuration definition information (step ST5), and then updates the I from the PIO type database 4-2. By acquiring information such as the number of / O points (step ST6), necessary information such as increase / decrease in the number of records in the application database 4-4 is acquired, and application database such as I / O database generation, RAS information, and alarm messages 4-4 is automatically generated (step ST7).

  Information necessary for the system configuration information automatic generation function unit 4-3 to automatically generate the application database 4-4 is stored in the PIO type database 4-2.

  As described above, according to the second embodiment of the present invention, it is possible to automatically generate an application database associated with addition / deletion / replacement of a PIO device.

In the second embodiment, as described above, the engineering server has an application database in which at least one application data of I / O points, RAS information, and alarm message is registered, and PIO expansion, PIO removal, In response to the PIO replacement, the system configuration information automatic generation function unit updates the application database.
Further, the engineering server has an application database in which at least one application data of I / O points, RAS information, and an alarm message is registered, and the system configuration information automatic generation function unit is registered in the application database. A plant monitoring control system that collects information, determines whether the collected information is different from information registered in the application database, and updates the application database to actual information when the information is different. .

Embodiment 3 FIG.
A third embodiment of the present invention will be described below with reference to FIGS. FIG. 5 is a diagram showing still another example of the system configuration, and FIG. 6 is a flowchart for explaining the operation of FIG. The third embodiment has an OPS type database 4-5, and the contents used in the first and second embodiments described above can be processed when an OPS is added / deleted / replaced. Different. The OPS type database 4-5 is set in the storage device 4M.

  In the third embodiment, as illustrated in FIG. 6, OPS1 (1-1) and OPS2 (1-2) in which the system S / W is installed (step ST1) are connected to the OPS network 5 (step ST2), and an “OPS network scan” operation is performed by the engineering server 4 (step ST3). When the OPS network scan operation is performed, the system configuration information automatic generation function unit 4-3 searches the current connection state of the OPS network (step ST4).

  Thereafter, the system configuration information automatic generation function unit 4-3 compares the system configuration definition information (information registered in the OPS type database 4-5) on the engineering data server 4 with the searched OPS connection information, A difference between the two is detected (step ST5). If a difference is detected between the two, the OPS type uniquely determined by the installed system S / W is searched from the OPS type database 4-5, and the corresponding system configuration information is acquired (step ST6). The acquired system configuration information is reflected in the system configuration definition, and the process is terminated (step ST6).

  In the OPS type database, data records are prepared for each OPS type (server, client, stand-alone, etc.), and each data attribute (duplication, connection destination server, operation S / W, network type, etc.) is defined. . Since the OPS is registered as to which type of OPS it is at the time of S / W installation, the system configuration definition data can be updated by inquiring the OPS type from the connected OPS by the engineering server 4.

  As described above, according to the third embodiment of the present invention, it is possible to easily add / delete / replace OPS even by a non-specialized engineer by automatically setting the update operation of the OPS system configuration definition information. I can do it.

In the third embodiment, as described above, the engineering server has an OPS type database in which information on the type of operator station is registered. The system configuration information automatic generation function unit is a plant monitoring control system that updates the OPS type database.
Whether the engineering server collects information registered in the OPS type database by the system configuration information automatic generation function unit and whether the collected information is different from the information registered in the OPS type database. It is a plant monitoring and control system that judges and updates the OPS type database to actual information when they are different.

Embodiment 4 FIG.
A fourth embodiment of the present invention will be described below with reference to FIGS. FIG. 7 is a diagram showing still another example of the system configuration, and FIG. 8 is a flowchart for explaining the operation of FIG. The fourth embodiment is different from the third embodiment described above in that the system configuration definition (OPS type database 4-5) can be automatically updated even in an OPS in which the system S / W is not installed. .

  In the above-described third embodiment, when an OPS in which no system S / W is installed is connected to the OPS network 5, the system configuration definition information cannot be updated because the OPS type cannot be determined. is there. In the fourth embodiment, when an OPS in which system S / W is not installed is detected, a screen for selecting the system S / W to be installed is displayed to the operator, and installation is performed on the spot. System configuration definition information can be automatically updated.

  Specifically, an OPS in which no system S / W is installed is connected to the OPS network 5 (step ST1), and an “OPS network scan” is executed by the engineering server 4 (step ST2). The configuration information automatic generation function unit 4-3 detects an OPS connection state to the OPS network (step ST3).

  The system configuration information automatic generation function unit 4-3 collates the system configuration definition data (for example, data registered in the OPS type database 4-5) in the engineering server with the searched OPS connection status (step ST4). ) To detect the difference between the two. If there is a difference between the two, the system configuration information automatic generation function unit 4-3 inquires whether the system S / W is installed in the newly detected OPS (step ST5).

If the system S / W is not installed (when the OPS type cannot be acquired), the operator is prompted to install the system S / W, and the system S / W selected by the operator is installed in the OPS ( Step ST6). The system configuration information automatic generation function unit 4-3 determines the OPS type based on the system S / W installed in the OPS (step ST7), and updates the data in the system configuration definition table 4-1 on the engineering server ( Step ST8).
The update result in step ST8 is the content added as, for example, OPS type X on the OPS type database in FIG.

As described above, according to the fourth embodiment of the present invention, the system configuration information can be automatically updated even for an OPS in which the system S / W is not installed. Also, since the installation status of the OPS system S / W is checked, it can be expected to prevent installation omissions and mistakes.
In Embodiment 4 of the present invention, when an operator star that does not have a system S / W installed that executes a plant monitoring control function is connected to the network, the operator star is not yet installed in the system S / W Is detected by the system configuration information automatic generation function unit, and when the system S / W is installed in the operator station, the system configuration information automatic generation function unit corresponds to the installed system S / W. A plant monitoring control system characterized by updating an OPS type database.

Embodiment 5 FIG.
The fifth embodiment of the present invention will be described below with reference to FIGS. FIG. 9 is a view showing still another example of the system configuration, and FIG. 10 is a flowchart for explaining the operation of FIG. In the third embodiment, the system configuration information automatic generation function unit 4-3 has a fixed-cycle scan function unit 4-31, and the PIO modules (PIO1, PIO2, PIO3,... ) 3-1, 3-2, 3-3,... 3-n connection status to the PIO network 6, and the OPS 1 (1-1) and OPS 2 (1-2) to the OPS network 5. Is automatically detected at regular intervals.

  Hereinafter, the operation in the fifth embodiment will be described.

  In the systems of the first to fourth embodiments, the system configuration information is not updated unless a network scan operation is performed by the engineering server 5 after connecting the PIO device and the OPS to the network. For this reason, when a large number of devices are added / deleted / replaced, it is necessary to perform a network scan each time, resulting in a problem that the operation becomes complicated.

  Therefore, by monitoring the PIO network 6 and the OPS network 5 at regular intervals, the addition / deletion / replacement information of the PIO device and OPS is detected in real time, and the system configuration definition information (the system configuration definition 4-1, the above-mentioned The PIO type database 4-2 and the information of the application database 4-4) can be automatically updated.

  Specifically, as illustrated in FIG. 9, the system configuration information automatic generation function unit 4-3 has a fixed-cycle scan function unit 4-31, and the function of the fixed-cycle scan function unit 4-31 As shown in FIG. 10, the PIO network 6 is scanned at regular intervals (step ST1), and the PIO connection state (PIO modules (PIO1, PIO2, PIO3,... PIOn) 3-1, 3-2, 3-3). ,..., 3-n) are searched and monitored (step ST2).

The system configuration information automatic generation function unit 4-3 acquires the PIO acquired by the scan.
It is determined whether or not the connection state matches the system configuration definition data (data in the system configuration definition table 4-1) (step ST3). The system configuration information automatic generation function unit 4-3 scans the system configuration definition data (data in the system configuration definition table 4-1) on the engineering server 4 when the two do not match as a result of the determination. Update to the latest PIO connection state (connection state of the PIO modules (PIO1, PIO2, PIO3,... PIOn) 3-1, 3-2, 3-3,..., 3-n) (step ST4). .

  Subsequently, the system configuration information automatic generation function unit 4-3 executes the network scan of the OPS (step ST5), and the OPS connection status to the OPS network 5 (the OPS1 (1-1), OPS2 (1 -2) is detected (connection state to the OPS network 5) (step ST4). The system configuration information automatic generation function unit 4-3 collates the system configuration definition data (data of the OPS type database 4-5) in the engineering server 4 with the searched OPS connection status (step ST7). The difference between the two is detected. If there is a difference between the two, the OPS type is determined by the system S / W installed in the OPS (step ST7), and the system configuration definition data (the data of the OPS type database 4-5) on the engineering server 4 is obtained. Update (step ST8).

  As described above, according to the fifth embodiment of the present invention, the system configuration definition information can be automatically updated without connecting with the PIO device and the OPS by simply connecting to the network. It becomes possible. As a result, when adding or removing PIO or OPS, the system automatically detects the difference in the system configuration status by simply connecting to the network without being aware of the system configuration, and automatically corrects the necessary database. And maintenance becomes easy.

  In the fifth embodiment, as described above, the system configuration information automatic generation function unit monitors the actual connection status of the PIO device to the network at regular intervals, and performs PIO expansion / PIO removal / PIO replacement. Correspondingly, the system configuration information automatic generation function unit is a plant monitoring and control system in which the system configuration definition table is updated, and the system configuration information automatic generation function unit actually connects the PIO device to the network. The status is monitored at regular intervals, and the system configuration definition table is updated in response to the addition / removal / replacement of the PIO module constituting the PIO device, and the actual connection status of the operator station to the network is defined. A program that periodically monitors and updates the OPS type database in response to the expansion / removal / replacement of the operator station. It is a door monitoring and control system.

  In addition, in each figure of FIG.1, FIG.3, FIG.5, FIG.7 and FIG. 9, the same code | symbol shows the same or equivalent part.

It is a figure which shows Embodiment 1 of this invention, and is a figure which shows an example of a system configuration | structure. FIG. 5 is a diagram showing the first embodiment of the present invention, and is a flowchart for explaining the operation of FIG. 1. It is a figure which shows Embodiment 2 of this invention, and is a figure which shows the other example of a system configuration. It is a figure which shows Embodiment 2 of this invention, and is a flowchart figure for demonstrating operation | movement of FIG. It is a figure which shows Embodiment 3 of this invention, and is a figure which shows the further another example of a system configuration. It is a figure which shows Embodiment 3 of this invention, and is a flowchart figure for demonstrating operation | movement of FIG. It is a figure which shows Embodiment 4 of this invention, and is a figure which shows the further another example of a system configuration. It is a figure which shows Embodiment 4 of this invention, and is a flowchart figure for demonstrating operation | movement of FIG. It is a figure which shows Embodiment 5 of this invention, and is a figure which shows the further another example of a system configuration. It is a figure which shows Embodiment 5 of this invention, and is a flowchart figure for demonstrating operation | movement of FIG. It is a figure which shows the data update flow in the conventional plant monitoring system.

Explanation of symbols

1-1, 1-2 operator station,
2 control device,
2-1. Storage device,
3 PIO (Program I / O transfer) device,
3-1, 3-2, 3-3, 3-n PIO module,
4 Engineering server,
4-1 System configuration definition table,
4-2 PIO type database
4-3 System configuration information automatic generation function part,
4-4 Application database,
4-5 OPS (Operator Station) type database,
4M storage device,
5 OPS network,
6 PIO network.

Claims (6)

  A plant monitoring and control system including a control device that transmits and receives monitoring control signals to and from plant components via a PIO device on the network, and an operator station that is connected to the control device via a network and performs monitoring and control via the control device A system configuration definition table that is connected to a network to which the control device and the operator station are connected, and in which connection information of the control device and connection information of the PIO device corresponding to the control device are registered And the actual connection information of the control device and the control device collected by collecting the actual connection information of the control device and the actual connection information of the PIO device corresponding to the control device via the network. Actual connection information of the PIO device corresponding to the system configuration definition table It is determined whether or not the connection information of the registered control device and the connection information of the PIO device corresponding to the control device are different, and if they are different, the system configuration definition table is displayed as the control device. A plant monitoring and control system comprising an engineering server having a system configuration information automatic generation function unit that updates the actual connection information and the actual connection information of the PIO device corresponding to the control device.   2. The plant monitoring control system according to claim 1, wherein the engineering server has an application database in which at least one application data of I / O points, RAS information, and an alarm message is registered, and the system configuration information is automatically generated. The function unit collects information registered in the application database and determines whether or not the collected information is different from the information registered in the application database. A plant supervisory control system characterized by updating to information.   3. The plant monitoring control system according to claim 1, wherein the engineering server collects information registered in the OPS type database by the system configuration information automatic generation function unit, and the collected information is the OPS type database. A plant monitoring control system characterized in that it is determined whether or not the information is different from the information registered in the information, and if the information is different, the OPS type database is updated to actual information. 4. The plant monitoring control system according to claim 3, wherein when an operator star that has not been installed in a system S / W that executes a plant monitoring control function is connected to the network, the operator star is not installed in the system S / W. When the system configuration information automatic generation function unit detects that the system S / W is installed in the operator station, the system configuration information automatic generation function corresponds to the installed system S / W. A plant monitoring control system, wherein the unit updates the OPS type database.   3. The plant monitoring and control system according to claim 1 or 2, wherein the system configuration information automatic generation function unit monitors the actual connection status of the PIO device to the network at a regular cycle, and PIO expansion / PIO removal The plant monitoring control system, wherein the system configuration information automatic generation function unit updates the system configuration definition table in response to / PIO replacement.   5. The plant monitoring control system according to claim 3 or 4, wherein the system configuration information automatic generation function unit monitors an actual connection status of the PIO device to the network at a fixed period to configure the PIO device. The system configuration definition table is updated in response to the expansion / removal / replacement of PIO modules to be monitored, the actual connection status of the operator station to the network is monitored at regular intervals, and the operator station station is expanded / removed. / Plant monitoring control system, wherein the OPS type database is updated in response to replacement.

Images