JP2022144841A - New/old supervisory control switching system, switching method for new/old supervisory control switching system - Google Patents

Abstract

To provide a new/old supervisory control switching system that enables switching from an old supervisory control system to a new supervisory control system without requiring a relay device.SOLUTION: When controllers 201 and 202 are connected to an old supervisory control system 10 by a first network 251 and a second network 252, the controllers communicate with the old supervisory control system through the first network or the second network. Also, when the controllers are connected to the old supervisory control system by the first network and are connected to a new supervisory control system to the second network, the controllers communicate with the old supervisory control system through the first network and with the new supervisory control system through the second network. Further, when the controllers are connected to the new supervisory control system by the first network and the second network, the controllers communicate with the old supervisory control system through the first network or the second network.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to a new/old supervisory control switching system and a method of switching between a new/old supervisory control switching system.

Water treatment facilities related to water supply and sewage systems, incineration facilities, factories, and the like are provided with a monitoring control system for monitoring the operation of equipment and the like. In the supervisory control system, an existing system (old supervisory control system) may be updated with a new system (new supervisory control system). Normally, updating from an existing system to a new system is required to be executed without stopping facility operation and supervisory control.

FIG. 13 is a system configuration diagram for explaining a switching method in a conventional supervisory control system (see Patent Document 1).

The supervisory control system shown in FIG. 13 includes a lower system 2, an old system 3, a new system 4, and a relay device 5. In FIG. The lower system 2 is a system that controls the operations of the controlled devices 9-1 to 9-N. The lower system 2 includes controllers 21-1 to 21-N. The controller 21-i controls the operation of the controlled device 9-i. Control target devices 9-1 to 9-N are devices to be monitored or controlled by the supervisory control system.

The old system 3 is an existing upper system that monitors or controls the lower system 2 . The old system 3 comprises a monitoring operation terminal 31 and monitoring control servers 32-1 and 32-2. The monitoring operation terminal 31 has a function of providing a user interface for monitoring or controlling the lower system 2 . The supervisory control servers 32-1 and 32-2 have the function of performing various data processing related to the monitoring or control of the lower system 2. FIG.

The new system 4 is a newly installed upper system that monitors or controls the lower system 2 . Specifically, the new system 4 includes a monitoring operation terminal 41 similar to the monitoring operation terminal 31, and monitoring control servers 42-1 and 42-2 similar to the monitoring control server 32. have a function. Hereinafter, the supervisory control servers 42-1 and 42-2 will be referred to as the supervisory control server 42 unless otherwise distinguished.

The relay device 5 is a communication device having a function of relaying communication among the lower system 2, the old system 3, and the new system 4. FIG. The relay device 5 is a communication device such as a layer 2 switch or a layer 3 switch.

The lower system 2, the old system 3, and the new system 4 are accommodated in different LANs (Local Area Networks). The lower system 2 is accommodated in the lower LAN 20, the old system 3 is accommodated in the old upper LAN 30, and the new system 4 is accommodated in the new upper LAN 40, respectively.

In the conventional monitoring and control system shown in FIG. 13, a relay device 5 is provided to cut off communication between the old system 3 and the new system 4, and relay communication between each higher system and the lower system 2. .

JP 2019-117524 A

The problems to be solved by the embodiments of the present invention are a new/old monitoring control switching system that enables switching from an old monitoring control system to a new monitoring control system without requiring a relay device, and switching between the old/new monitoring control switching system. to provide a method.

According to the embodiment, the new/old supervisory control switching system has a controller, an old supervisory control system, a new supervisory control system, and a transmission line. The controller transmits status data indicating the operating status of the equipment. The old monitoring and control system acquires the state data from the controller and monitors the operating state of the equipment. The new monitoring and control system acquires the state data from the controller and monitors the operating state of the equipment. A transmission line connects the controller, the old supervisory control system, and the new supervisory control system through a first network and a second network, respectively. When the controller is connected to the old supervisory control system by the first network and the second network, the controller communicates with the old supervisory control system through at least the first network or the second network. Further, when the controller is connected to the old supervisory control system by the first network and is connected to the new supervisory control system by the second network, the controller is connected to the old supervisory control system through the first network. and communicate with the new supervisory control system over the second network. Further, when the controller is in a state of being connected to the new supervisory control system by the first network and the second network, the controller communicates with the old supervisory control system through at least the first network or the second network. do.

1 is a block diagram showing an outline of the configuration of a new/old monitoring control switching system according to the present embodiment; FIG. FIG. 2 is a block diagram showing the configuration of a controller according to the embodiment; FIG. FIG. 2 is a block diagram showing the configurations of an old server and a new server in this embodiment; The figure which shows the structural example which implemented the relay apparatus (A system) and the relay apparatus (B system). 4 is a flow chart showing the operation of the switching method of the new/old monitoring control switching system according to the present embodiment. The figure which shows the change of the network which connects an old supervisory control system, a new supervisory control system, and a controller. The figure which shows the change of the network which connects an old supervisory control system, a new supervisory control system, and a controller. The figure which shows the change of the network which connects an old supervisory control system, a new supervisory control system, and a controller. FIG. 4 is a diagram for explaining a specific example of a transmission type setting unit according to the embodiment; FIG. 4 is a diagram for explaining a specific example of a transmission type setting unit according to the embodiment; FIG. 5 is a diagram for explaining a specific example of generating third abnormality detection data according to the embodiment; FIG. 5 is a diagram for explaining a specific example of generating third abnormality detection data according to the embodiment; FIG. 3 is a block diagram for explaining a switching method in a conventional monitoring control system;

Hereinafter, this embodiment will be described with reference to the drawings.

FIG. 1 is a block diagram showing the outline of the configuration of the new/old monitoring control switching system of this embodiment. The new/old supervisory control switching system includes an old supervisory control system 10 , a new supervisory control system 100 , and controllers 201 and 202 .

The old and new supervisory control switching system constructs the new supervisory control system 100 while continuing the operation of the old supervisory control system 10, and uses a relay device to connect the controllers 201, 202 and the old supervisory control system 10. Instead, the connection between the controllers 201 and 202 and the new supervisory control system 100 is changed to switch from the old supervisory control system 10 to the new supervisory control system 100 .

The controllers 201 and 202 are sub-systems that control the operation of facility equipment and the like (not shown) to be monitored and controlled by the monitoring control system. Although two controllers 201 and 202 are shown in FIG. 1, one controller or three or more controllers may be provided. One or more pieces of equipment are connected to the plurality of controllers 201 and 202, respectively, and various data indicating the operating state of the equipment (for example, state, failure, and measurement data) are collected, and the old monitoring control system 10 or the new Send to the supervisory control system 100 .

The old supervisory control system 10 is a host system that monitors or controls the controllers 201 and 202 . The old supervisory control system 10 includes an old supervisory control device 1 and an old server 11 . The old supervisory control device 1 acquires data indicating the operating state of equipment connected to the controllers 201 and 202, and has a function of outputting control instructions (operation output/set value data) for the equipment to the controllers 201 and 202. have. The old server 11 has a function of performing various data processing related to monitoring or controlling the lower system. In FIG. 1, only one old monitoring control device 1 and one old server 11 are shown, but a plurality of each may be provided.

The new supervisory control system 100 is a newly installed host system that monitors or controls the controllers 201 and 202 . The new supervisory control system 100 includes a new supervisory control device 101 and an old server 11 which are similar to the old supervisory control device 1 and the old server 11 provided in the old supervisory control system 10. Has functionality or extended functionality.

In the new/old supervisory control switching system, the controllers 201 and 202, the old supervisory control system 10, and the new supervisory control system 100 are interconnected by redundant transmission lines. FIG. 1 shows an example of connection via a duplicated LAN (Local Area Network). The duplexed LAN includes an A-system network (first network) and a B-system network (second network).

The controllers 201 and 202 are connected by a redundant network with a control system (A system) 251 and a control system (B system) 252 .

The old supervisory control device 1 and the old server 11 of the old supervisory control system 10 are connected by a duplicated network by the old supervisory control system control system (A system) 51 and the old supervisory control system control system (B system) 52. . When the old supervisory control system 10 is operated, the old supervisory control system control system (A system) 51 and the control system (A system) 251 are connected via the control system (A system) 351, and the old supervisory control A system control system (B system) 52 and a control system (B system) 252 are connected via a control system (B system) 352 .

The new supervisory control device 101 and the new server 111 of the new supervisory control system 100 are connected by a network that is duplicated by the new supervisory control system control system (A system) 151 and the new supervisory control system control system (B system) 152. . When the new supervisory control system 100 is operated, the new supervisory control system control system (A system) 151 and the control system (A system) 251 are connected via the control system (A system) 451, and the new supervisory control system A system control system (B system) 152 and a control system (B system) 252 are connected via a control system (B system) 452 .

The old supervisory control system 10, the new supervisory control system 100, and the controllers 201 and 202 are connected by a duplicated network, so that even if one network (for example, system A) fails, the other network (for example, B system) to continue processing for control and monitoring.

Therefore, the old supervisory control device 1 and the old server 11 of the old supervisory control system 10 are connected when either the control system (A system) 351 or the control system (B system) 352 is disconnected. Through the other control system (A system) 351 or control system (B system) 352, communication with the controllers 201 and 202 can be executed to continue the operation.

Similarly, the new supervisory control device 101 and the new server 111 of the new supervisory control system 100 are connected when either the control system (A system) 451 or the control system (B system) 452 is connected. Through the control system (A system) 351 or the control system (B system) 352 in the state, communication with the controllers 201 and 202 can be performed to execute operations. Also, when the new supervisory control device 101 and the new server 111 are connected by both the control system (A system) 451 and the control system (B system) 452, the monitoring control operation can be executed in a redundant state. can be done.

FIG. 2 is a block diagram showing the configuration of controllers 201 and 202 in this embodiment.

The controllers 201 and 202 include a CPU (Central Processing Unit), a memory, an auxiliary storage device, and the like, which are connected via a bus, and implement various functions by the CPU executing programs stored in the memory. The controllers 201 and 202 function as devices including a control unit 211, an input unit 212, a display unit 213, a communication unit 214, and a storage unit 215 by executing programs.

The control unit 211 executes various processes related to control of facility equipment to be controlled. The control unit 211 is provided with the functions of a transmission type setting unit 211A and a state monitoring unit 211B.

The transmission type setting unit 211A sets which transmission type, broadcast transmission or multicast transmission, is used for each of the control system (system A (first network)) and the control system (system B (second network)). do. For example, the control system (A system) is broadcast by the old supervisory control system 10, the control system (B system) is multicast by the new supervisory control system 100, or the control system (A system) is multicast by the old supervisory control system 10. , the control system (B system) can be set to broadcast transmission of the new supervisory control system 100 . The control unit 211 can set the transmission type by the transmission type setting unit 211A while communicating with the old supervisory control system 10 and the new supervisory control system 100 . The control unit 211 transmits data to the old supervisory control system 10 or the new supervisory control system 100 through the communication unit 214 by broadcast transmission or multicast transmission according to the setting of the transmission type.

The state monitoring unit 211B receives (issues an alarm from) the old monitoring and control system 10 (old server 11) anomaly detection data (second 1 anomaly detection data) and anomaly detection data ( Second abnormality detection data) is received through the communication unit 214 to monitor the operating states of the old supervisory control system 10 and the new supervisory control system 100 . The state monitoring unit 211B generates abnormality detection data (third abnormality detection data) indicating the states of the old monitoring control system 10 and the new monitoring control system 100 based on the first abnormality detection data and the second abnormality detection data. , based on this abnormality detection data, it is possible to determine the abnormality of the devices in the system. That is, in the process of switching from the old supervisory control system 10 to the new supervisory control system 100, even if the old supervisory control system 10 and the new supervisory control system 100 are operated side by side, an abnormality can be correctly detected.

The input unit 212 is configured using an input device such as a keyword, mouse, or touch panel. Also, the input unit 212 may be a communication interface that connects the input device to the old supervisory control device 1 . The input unit 212 receives data input and control instructions for the old monitoring control device 1 and outputs them to the control unit 211 .

The display unit 213 includes a display device such as a liquid crystal display. Also, the display unit 213 may be an interface for connecting a display device. The display unit 213 displays a user interface (for example, setting screen) regarding monitoring or control of the controllers 201 and 202 .

The communication unit 214 is a communication interface that connects to a duplicated LAN (control system (A system) 251 and control system (B system) 252).

The storage unit 215 is configured using a storage device such as an HDD (Hard disk drive) device or an SSD (Solid State Drive) device. The storage unit 215 stores various information necessary for operation. For example, the storage unit 215 stores a program for executing monitoring control processing, data referred to when executing the program, and the like. Further, the storage unit 215 stores identification definition information for identifying the old supervisory control system 10 and the new supervisory control system 100 .

For example, the control unit 211 determines whether or not the received data received through the communication unit 214 includes identification information of the new supervisory control system 100 . If the received data contains the identification information of the new supervisory control system 100 defined by the identification definition information, the control unit 211 determines that the transmission source is the new supervisory control system 100, and the identification information is not included. If not, it is determined that the transmission source is the old supervisory control system 10 . Therefore, the old supervisory control system 10 does not need to change the program (upgrade the software) such as adding identification information different from that of the new supervisory control system 100 to the data when the supervisory control system is switched.

FIG. 3 is a block diagram showing the configurations of the old server 11 and the new server 111 in this embodiment.

The old server 11 and the new server 111 are equipped with CPUs (Central Processing Units), memories, auxiliary storage devices, etc., which are connected via a bus, and realize various functions by the CPUs executing programs stored in the memories. The old server 11 and the new server 111 function as devices including a control unit 121, an input unit 122, a display unit 123, a communication unit 124, and a storage unit 125 by executing programs.

The control unit 121 executes various processes related to control of facility equipment to be controlled. The control unit 121 has a function of providing various types of data (for example, state/failure/measurement data) indicating the operating state of equipment received from the controllers 201 and 202 to the monitoring control device. Also, the control unit 121 is provided with the function of the state information transmission unit 121A.

The status information transmission unit 121A transmits data of status information indicating the status of devices in the system to the controllers 201 and 202 . The status information transmission unit 121A of the old server 11 collects the status information of the old monitoring control device 1 in the system, and sends the first abnormality detection data indicating the status information of the own device (old server 11) and the old monitoring control device 1. Generate and transmit to the controllers 201 and 202 . The new server 111 of the new supervisory control system 100 collects the state information of the new supervisory control device 101 in the system, and generates the second abnormality detection data indicating the state information of the own device (new server 111) and the new supervisory control device 101. Generate and transmit to the controllers 201 and 202 .

The input unit 122 is configured using an input device such as a keyword, mouse, or touch panel. Also, the input unit 122 may be a communication interface that connects an input device to the new supervisory control device 101 . The input unit 122 accepts data input and control instructions for the new supervisory control device 101 and outputs them to the control unit 121 .

The display unit 123 includes a display device such as a liquid crystal display. Also, the display unit 123 may be an interface for connecting a display device. The display unit 123 displays a user interface (for example, operation screen) regarding monitoring or control of the controllers 201 and 202 .

The communication unit 124 is a communication interface that connects to a duplicated LAN (control system (A system) and control system (B system)). The communication unit 124 of the old server 11 is connected to the old supervisory control system control system (A system) 51 and the old supervisory control system control system (B system) 52 . The communication unit 124 of the new server 111 is connected to the new supervisory control system control system (A system) 151 and the new supervisory control system control system (B system) 152 .

The storage unit 125 is configured using a storage device such as an HDD (Hard disk drive) device or an SSD (Solid State Drive) device. The storage unit 125 stores various information necessary for operation. For example, the storage unit 125 stores a program for executing monitoring control processing, data referred to when the program is executed, and the like.

Next, a method of switching from the old supervisory control system 10 to the new supervisory control system 100 will be described.

First, for comparison with the new/old supervisory control switching system in this embodiment, a case of executing switching from the old supervisory control system 10 to the new supervisory control system 100 using a relay device will be described.

FIG. 4 shows a configuration example in which a relay device (system A) 301 and a relay device (system B) 302 are mounted between the old supervisory control system 10 and the new supervisory control system 100 and the controllers 201 and 202. .

The A-system data of the operation output/set value data from the old supervisory control device 1 of the old supervisory control system 10 is transmitted from the old supervisory control system control system (A-system) 51 to the relay device (A-system) 301, the control system (A-system ) 251 to the controller 201 or controller 202 .

Similarly, the B system data of the operation output/set value data from the old supervisory control device 1 of the old supervisory control system 10 is transferred from the old supervisory control system control system (B system) 52 to the relay device (B system) 302, the control system It is transmitted to the controller 201 or the controller 202 via the (B system) 252 .

In addition, A-system data of status/failure/measurement data from the controller 201 or controller 202 passes through the control system (A-system) 251 and the relay device (A-system) 301 to the old supervisory control system of the old supervisory control system 10 . It is transmitted from the system control system (A system) 51 to the old supervisory control device 1 and the old server 11 .

Similarly, the B-system data of the state/failure/measurement data of the controller 201 or controller 202 is sent via the control system (B-system) 252 and relay device (B-system) 302 to the old monitoring and control system 10 of the old monitoring and control system 10. It is transmitted from the control system (B system) 52 to the old monitoring control device 1 and the old server 11 .

On the other hand, the A system data of the operation output/set value data from the new supervisory control device 101 of the new supervisory control system 100 is transmitted from the new supervisory control system control system (A system) 151 to the relay device (A system) 301, the control system ( A system) 251 to the controller 201 or the controller 202 .

Similarly, the B system data of the operation output/set value data from the new supervisory control device 101 of the new supervisory control system 100 is transmitted from the new supervisory control system control system (B system) 152 to the relay device (B system) 302, the control system ( B system) 252 to the controller 201 or 202 .

System A data of status/failure/measurement data from the controller 201 or controller 202 is passed through the control system (A system) 251 and relay device (A system) 301 to the new monitoring control system 100 of the new monitoring control system 100. It is transmitted from the system control system (A system) 151 to the new supervisory control device 101 and the new server 111 .

Similarly, the B-system data of the state/failure/measurement data of the controller 201 or controller 202 is transmitted via the control system (B-system) 252 and the relay device (B-system) 302 to the new supervisory control system of the new supervisory control system 100. It is transmitted from the control system (B system) 152 to the new supervisory control device 100 and the new server 111 .

From the above, by using the relay device (A system) 301 and the relay device (B system) 302, the old supervisory control system (old supervisory control device 1, old server 11) and the new supervisory control system (new supervisory control device 101) , the network of the new server 111) is separated. Therefore, it is possible to prevent data from being mixed between the old supervisory control system 10 and the new supervisory control system 100, so that it can be effectively used in the transitional period of switching.

However, the relay device (system A) 301 and the relay device (system B) 302 are effective at the time of switching between the new and old supervisory control systems in parallel operation, but become unnecessary after the switching is completed. Therefore, switching in a short period of time incurs costs for purchasing the relay device (A system) 301 and the relay device (B system) 302 and operating costs such as securing an installation site.

Next, the operation of the switching method of the new/old monitoring control switching system in this embodiment will be described with reference to the flowchart shown in FIG. 6, 7, and 8 are diagrams showing changes in the network (control system (A system) (B system)) connecting the old supervisory control system 10, the new supervisory control system 100, and the controllers 201 and 202. FIG.

Step S1 in FIG. 5 shows a state before switching in which only the old monitoring and control system 10 is operated. At step S1, the new supervisory control system 100 is in an uninstalled state.

As shown in FIG. 6A, the controllers 201 and 202 include the old supervisory control device 1 and the old server 11 of the old supervisory control system 10, the A system network (old supervisory control system control system (A system) 51, A control system (A system) 351) is connected to a B system network (old supervisory control system control system (B system) 52, control system (B system) 352). The controllers 201 and 202 and the old supervisory control system 10 communicate with each other to perform supervisory control of facility equipment.

Step S2 in FIG. 5 shows a state in which construction of the new supervisory control system 100 is started. The new supervisory control system 100 is constructed while continuing the operation of the old supervisory control system 10 .

As shown in FIG. 6B, the controllers 201 and 202 are in a state of being connected to the old supervisory control system 10 via the A-system network and the B-system network. On the other hand, the controllers 201 and 202 are connected to the new server 111 of the new supervisory control device 100, and the new supervisory control device 101 is connected to the system A network (new supervisory control system control system (A system) 151), the system B network (new monitor It is in a state in which it is not connected to any of the control system control system (B system) 152).

The controllers 201 and 202 and the old supervisory control system 10 continue to communicate with each other and perform supervisory control of facility equipment.

Step S3 in FIG. 5 is a preparatory step for operating the old supervisory control system 10 and the new supervisory control system 100 side by side. As shown in FIG. 7A, in the old supervisory control system 10, the connection by the control system (B system) 352 is stopped, and the old supervisory control system control system (B system) 52 and the control system (B system) 252 are connected. line break. The controllers 201 and 202 are connected only to the old supervisory control system control system (A system).

The controllers 201 and 202 and the old supervisory control system 10 are connected only by one system A network (old supervisory control system control system (A system) 51, control system (A system) 351, control system (A system) 251) It is operated and performs supervisory control of facility equipment.

Step S4 in FIG. 5 is a step of connecting the new supervisory control system 100 to the controllers 201 and 202. FIG. As shown in FIG. 7B, only the new supervisory control system control system (B system) 152 of the new supervisory control system 100 is connected to the control system (B system) 252 via the control system (B system) 452. . Therefore, the controllers 201 and 202 are connected to the new supervisory control system 100 via the B system network (new supervisory control system control system (B system) 152, control system (B system) 452, control system (B system) 252)). (new server 111, new supervisory control device 101). At this time, the controllers 201 and 202 are not connected to the system A network of the new supervisory control system 100 (new supervisory control system control system (A system) 151).

Step S5 in FIG. 5 is a step of operating the old supervisory control system 10 and the new supervisory control system 100 side by side. As shown in FIG. 7B, the old supervisory control system 10 (old supervisory control device 1, old server 11) includes an A system network (old supervisory control system control system (A system) 51, control system (A system) 351, the control system (A system) 251) is connected to the controllers 201 and 202, and the new supervisory control system 100 (new supervisory control device 100, new server 111) connects to the B system network (new supervisory control system control system ( B system) 152, control system (B system) 452, and control system (B system) 252).

As a result, since the old supervisory control system 10 and the new supervisory control system 100 do not have a mixed control system LAN, the data sent and received to and from the controllers 201 and 202 do not mix, and parallel operation is possible.

Also, since the old supervisory control system 10 is connected to the controllers 201 and 202 only through the A system network, and the new supervisory control system 100 is connected to the controllers 201 and 202 only through the B system network, redundancy is provided. do not have. However, since monitoring can be performed by both the new supervisory control system 100 and the old supervisory control system 10, the system is in a redundant state, and operation can be continued even if one of the supervisory control systems becomes abnormal. Also, if the co-located operation period is short, this risk is almost non-existent.

As described above, in the new/old monitoring control switching system of this embodiment, like the old/new monitoring control switching system shown in FIG. Since there is no need to install the relay device B system 302, there is no need to purchase the relay device (A system) 301 and the relay device B system 302 and to secure an installation location, so that costs can be reduced.

Step S6 in FIG. 5 is a step of removing the old supervisory control system 10 from the parallel operation of the old supervisory control system 10 and the new supervisory control system 100 . As shown in FIG. 8A, in the old supervisory control system 10, the connection by the control system (A system) 351 is stopped, and the old supervisory control system control system (A system) 51 and the control system (A system) 251 line break. As a result, the controllers 201 and 202 are disconnected from the old supervisory control system 10 .

The controllers 201 and 202 and the new supervisory control system 100 are connected only by one system B network (new supervisory control system control system (B system) 152, control system (B system) 452, control system (B system) 252). It is operated and performs supervisory control of facility equipment.

Step S7 in FIG. 5 is the final step operated only by the new supervisory control system 100. FIG. As shown in FIG. 8B, the new supervisory control system control system (A system) 152 of the new supervisory control system 100 is connected to the control system (A system) 251 via the control system (A system) 451 . Therefore, the controllers 201 and 202 are connected to the A system network (new supervisory control system control system (A system) 151, the control system (A system) 451, the control system (A system) 251) and the B system network (new supervisory control system Connected to new supervisory control system 100 (new server 111, new supervisory control device 101) via control system (B system) 152, control system (B system) 452, control system (B system) 252)) . Therefore, the new supervisory control system 100 and the controllers 201 and 202 are in a state of being able to communicate with each other and execute supervisory control of facility equipment. This completes the switching from the old supervisory control system 10 to the new supervisory control system 100 .

Thus, in the new/old supervisory control switching system in this embodiment, as shown in FIG. 301 and the relay device B system 302 are not installed, and data of the new and old monitoring and control systems can be switched without interfering with each other.

Therefore, it is possible to reduce costs because it is not necessary to mount a relay device. Moreover, since no relay device is mounted, a space for mounting the relay device is not required.

In addition, since there is no need to upgrade the software of the old supervisory control system, it is possible to reduce costs and reduce risks by not remodeling.

Next, a case of changing the transmission type of the control system LAN to the old supervisory control system 10 and the new control system supervisory control system 100 will be described.

For example, state data is transmitted from the controllers 201 and 202 to the old supervisory control system 10 by broadcast transmission, and to the new supervisory control system 100 by multicast transmission. Conventionally, when changing the type of transmission to the supervisory control system, the controllers 201 and 202 are stopped and the data transmission functions of the controllers 201 and 202 are switched. Moreover, when switching the transmission type, it is necessary to set both the control system A system and the control system B system to the same transmission type. For example, when switching from broadcast transmission to multicast transmission, both the control system A system and the control system B system are switched to multicast transmission.

In the controllers 201 and 202 according to the present embodiment, the transmission type setting section 211A provided in the control section 211 can individually change the transmission type for each of the control system A and the control system B. Therefore, it is possible to set broadcast transmission for one system and multicast transmission for the other system.

In the new/old supervisory control switching system according to the present embodiment, parallel operation of the old supervisory control system 10 and the new supervisory control system 100 is performed in the state shown in FIG. 7(B).

Therefore, for example, even if the old supervisory control system 10 supports only broadcast transmission and the new supervisory control system 100 supports multicast transmission, the control system A connected to the old supervisory control system 10 system is set to broadcast transmission, and control system B is set to multicast transmission. As a result, it is possible to smoothly switch from the old supervisory control system 10 to the new supervisory control system 100 without causing a failure or the like due to a difference in transmission type.

In addition, when the old supervisory control system 10 and the new supervisory control system 100 are operated side by side, the one-system control system LAN is disconnected, so broadcast transmission and multicast transmission do not coexist. Further, for example, if the new supervisory control system 100 is compatible with both broadcast transmission and multicast transmission, it becomes possible to switch the transmission type while being connected.

9 and 10 are diagrams for explaining a specific example of the transmission type setting section 211A in this embodiment.

FIG. 9 shows an example of a configuration in which the controllers 201 and 202 are controlled by ladder software (program). As shown in FIG. 9, the ladder software has a function (transmission type setting unit 211A) capable of setting broadcast transmission or multicast transmission for each of the control system A system ("BROADCAST_A") and the control system B system ("BROADCAST_B"). set up.

For example, when the transmission type setting is instructed by the input unit 212, the control unit 211 causes the display unit 213 to display the setting screen shown in FIG.

The control unit 211 sets broadcast transmission by setting the number in the LD of the ladder software shown in FIG. set up multicast transmission.

Control units 211 of controllers 201 and 202 control system A (control system (A system) 251) and control system B (control system (B ) 252) is performed by broadcast transmission or multicast transmission.

Note that the control unit 211 receives a transmission type setting request online from the old server 11, the new server 111, or an information processing device (such as a personal computer) (not shown) connected via a network. The setting screen shown in FIG. 9 may be displayed on the original device. The control unit 211 receives the setting content and stores it in the storage unit 215 (online switching) when the setting operation is performed in the requesting device in the same manner as described above. The control unit 211 switches the transmission type according to the setting contents.

Conventionally, switching is performed by stopping the controllers 201 and 202, but with ladder software, it is possible to change the settings while the controllers 201 and 202 are in operation. Therefore, in the process of switching from the old supervisory control system 10 to the new supervisory control system 100, the supervisory control can be continued without stopping the controllers 201 and 202. FIG.

FIG. 10 is a diagram showing an example of a setting function (transmission type setting section 211A) different from that in FIG. As shown in FIG. 10, a function (transmission type setting 211A) is provided. In the example of FIG. 10, the control system A system and the control system B system can be individually selected from a pull-down menu or the like to select broadcast transmission or multicast transmission.

For example, when the transmission type setting is instructed by the operation of the input unit 212, the control unit 211 causes the display unit 213 to display the setting screen shown in FIG.

The control unit 211 sets broadcast transmission or multicast transmission in the respective pull-down menus of the control system A system and the control system B system shown in FIG.

Control units 211 of controllers 201 and 202 control system A (control system (A system) 251) and control system B (control system (B ) 252) is performed by broadcast transmission or multicast transmission. Also, in the same manner as described above, online switching may be enabled.

The new supervisory control system 100 (new supervisory control device 100, new server 111) and controllers 201 and 202 are compatible with both broadcast transmission and multicast transmission. The old supervisory control system 10 may also be upgraded to be compatible.

Next, state monitoring of the old monitoring control system 10 and the new monitoring control system 100 by the controllers 201 and 202 of the new/old monitoring control switching system in this embodiment will be described.

The old server 11 of the old supervisory control system 10 detects the states of the devices (the old supervisory control device 1 and the old server 11) in the system, and transmits first abnormality detection data indicating the state information of each device to the controllers 201 and 202. Send to Also, the new server 111 of the new supervisory control system 100 detects the state of the devices (the new supervisory control device 101, the new server 111) in the system, and sends the second abnormality detection data indicating the state information of each device to the controller 201. , 202.

The controllers 201 and 202 use the state monitoring section 211B of the control section 211 to monitor the system state based on the first abnormality detection data or the second abnormality detection data transmitted from the old supervisory control system 10 and the new supervisory control system 100. (the status of whether the connected device is started normally).

In the new/old supervisory control switching system according to the present embodiment, parallel operation of the old supervisory control system 10 and the new supervisory control system 100 is performed in the state shown in FIG. 7(B). In this state, if the first anomaly detection data is received from the old supervisory control system 10 and the second anomaly detection data is received from the new supervisory control system 100, the state information may be mixed or chattering (for example, the old supervisory control A situation may occur in which stable abnormality monitoring cannot be performed, such as alternately receiving abnormality detection data indicating that the equipment of the system 10 is abnormal and the equipment of the new monitoring and control system 100 is normal.

In the new/old supervisory control switching system in this embodiment, based on the anomaly detection data received from each of the old supervisory control system 10 and the new supervisory control system 100, the third anomaly detection data indicating the state information of the new/old supervisory control system is generated, and anomaly monitoring is performed based on the third anomaly detection data.

A specific example of generating the third abnormality detection data in this embodiment will be described below.

As shown in FIG. 11A, the format of the abnormality detection data transmitted from the old server 11 and the new server 111 is set. In the example shown in FIG. 11A, 1-word (2-byte) data is prepared, 0 bit is unused, and 1 to F bits are assigned to station numbers (STN1 to STN15), respectively.

When an abnormality occurs in a device in the system, abnormality detection data is generated in which the bit of the station number corresponding to the device in which the abnormality has occurred is set to "1". Controllers 201 and 202 determine that an abnormality has occurred in the device corresponding to the station number when the received abnormality detection data includes a station number that has changed from "0" to "1."

Therefore, when there is a device in which an abnormality has occurred only in one of the monitoring and control systems, the controllers 201 and 202 provide the abnormality detection data in which the bit of the station number corresponding to the device in which the abnormality has occurred is set to "1", Receives (chatters) anomaly detection data in which the bit of the same station number is set to "0".

To prevent chattering, the third anomaly detection data is generated as follows.

FIG. 11B shows setting of station numbers for devices connected to the old supervisory control system 10 such as the old supervisory control device 1 and the old server 11 of the old supervisory control system 10 .

In the example shown in FIG. 11(B), there are three old supervisory control devices 1 with station numbers 1, 2, and 3, and one old server 11 with a station number of 11(B). is shown.

FIG. 11C shows setting of station numbers connected to the new supervisory control system 100 such as the new supervisory control device 101 and the new server 111 of the new supervisory control system 100 .

In the example shown in FIG. 11(C), there are three new supervisory control devices 101 with station numbers of 8, 9, and 10, and one new server 111 with a station number of 12(C). is shown.

At this time, it is assumed that the station numbers of the old supervisory control system 10 and the new supervisory control system 100 do not overlap.

FIGS. 12A and 12B show examples of chattering. As shown in FIG. 12(A), in the first anomaly detection data from the old supervisory control device 1, the station number 1 with "1" indicating an anomaly is the second anomaly detected data from the new supervisory control device 101. Station number 1 of the data is set to "0" so that the abnormality is OFF.

Therefore, the state monitoring unit 211B masks the first anomaly detection data shown in FIG. 12(A) with the station number setting data for the first anomaly detection data of the old monitoring control system 10 shown in FIG. 11(B). (AND) Execute processing. In addition, the state monitoring unit 211B masks the second anomaly detection data shown in FIG. 12(B) with data for setting the station number for the second anomaly detection data of the new supervisory control system 100 shown in FIG. 11(C). (AND) Execute processing.

Then, the state monitoring unit 211B ORs the mask data of the first abnormality detection data and the mask data of the second abnormality detection data to obtain the third abnormality detection data of the old and new monitoring control systems as shown in FIG. 12(C). Data can be created.

The state monitoring unit 211B monitors the states of the devices of the old monitoring and control system 10 and the new monitoring and control system 100 based on the third abnormality detection data. Therefore, as shown in FIG. 7B, even in a situation where the old supervisory control system 10 and the new supervisory control system 100 are operated side by side, it is possible to continue to perform correct supervisory control. be.

In this embodiment, when the old supervisory control system is switched to the new supervisory control system, the old supervisory control system is connected to the controller by the control system A system, and the new supervisory control system is connected to the controller by the control system B system. , this embodiment is presented as an example. When switching from the old supervisory control system to the new supervisory control system, the old supervisory control system may be connected to the controller by the control system B, and the new supervisory control system may be connected to the controller by the control system A system. In that case, the control system A system is the second network, and the control system B system is the first network.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

In addition, the processing described in the above-described embodiments can be performed by using a recording medium such as a magnetic disk (flexible disk, hard disk, etc.), an optical disk (CD-ROM, DVD, etc.), a semiconductor memory, etc. as a program that can be executed by a computer. can be written to and provided to various devices. Moreover, it is also possible to transmit it by a communication medium and provide it to various devices. The computer reads a program recorded on a recording medium or receives the program via a communication medium, and executes the above-described processes by being controlled by the program.

1 Old supervisory control device 11 Old server 51 Old supervisory control system control system (A system) 52 Old supervisory control system control system (B system) 101 New supervisory control device 111 New server 151... New supervisory control system control system (A system) 152... New supervisory control system control system (B system) 201, 202... Controllers 121, 211... Control unit 121A... Status information transmission unit 211A... Transmission type Setting unit 211B State monitoring unit 122, 212 Input unit 123, 213 Display unit 124, 214 Communication unit 125, 215 Storage unit 251 Control system (A system) 252 Control system (B system).

Claims (6)

a controller that transmits state data indicating the operating state of the equipment;
an old monitoring and control system that acquires the state data from the controller and monitors the operating state of the equipment;
a new monitoring and control system that acquires the state data from the controller and monitors the operating state of the equipment;
a transmission path connecting the controller, the old supervisory control system, and the new supervisory control system via a first network and a second network, respectively;
The controller is
when the old supervisory control system is connected to the first network and the second network, communicate with the old supervisory control system through at least the first network or the second network;
when the old supervisory control system is connected to the first network and the new supervisory control system is connected to the second network, communicating with the old supervisory control system through the first network; Communicate with the new supervisory control system through a network,
When the new supervisory control system is connected to the first network and the second network, communicating with the new supervisory control system through at least the first network or the second network;
Old and new monitoring control switching system. The controller is
Broadcast transmission of the old supervisory control system on the first network, multicast transmission of the new supervisory control system on the second network, or multicast transmission of the old supervisory control system on the first network, and the new monitor on the second network 2. The new/old supervisory control switching system according to claim 1, wherein communication is performed by broadcast transmission of the control system. The controller is
3. The new/old supervisory control switching according to claim 1 or 2, further comprising a transmission type setting unit for setting whether communication is to be performed by either broadcast transmission or multicast transmission for each of said first network and said second network. system. 4. The new/old supervisory control switching system according to claim 3, wherein said controller executes transmission type setting by said transmission type setting unit in a state of communicating with said old supervisory control system or said new supervisory control system. The controller is
First anomaly detection data indicating the state of devices within the system, transmitted from the old supervisory control system, and second anomaly detection data indicating the state of devices within the system, transmitted from the new supervisory control system. 5. The new/old monitoring control switching system according to any one of claims 1 to 4, further comprising a state monitoring unit for generating third abnormality detection data indicating states of said old monitoring control system and said new monitoring control system. a controller that transmits state data indicating the operating state of the equipment;
an old monitoring and control system that acquires the state data from the controller and monitors the operating state of the equipment;
a new monitoring and control system that acquires the state data from the controller and monitors the operating state of the equipment;
A method for switching between a new and old supervisory control switching system having a transmission line connecting the controller, the old supervisory control system, and the new supervisory control system by a first network and a second network, respectively,
the controller is connected to the old supervisory control system by the first network and the second network, and communicates with the old supervisory control system through at least the first network or the second network;
The controller is connected to the old supervisory control system by the first network, is connected to the new supervisory control system by the second network, communicates with the old supervisory control system through the first network, and communicates with the old supervisory control system through the second network. communicating with the new supervisory control system through
The controller is connected by the new supervisory control system and the first network and the second network, and has a step of communicating with the new supervisory control system through at least the first network or the second network. A switching method for a monitoring control switching system.

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