JP7245742B2 - SCADA web HMI server device - Google Patents

Description

The present invention relates to a SCADA web HMI server device for operating SCADA HMI on a web browser.

SCADA (Supervisory Control And Data Acquisition) is known as a mechanism for monitoring and controlling social infrastructure systems. Social infrastructure systems include steel rolling systems, power transmission and transformation systems, water and sewage treatment systems, building management systems, and road systems.

SCADA is a kind of industrial control system and performs system monitoring and process control by computer. SCADA requires responsiveness (real-time capability) matching the processing performance of the system.

SCADA generally consists of the following subsystems.
(1) HMI (Human Machine Interface)
An HMI is a mechanism that presents data of a target process (monitored device) to an operator so that the operator can monitor and control the process. For example, Patent Literature 1 discloses a SCADA HMI provided with an HMI screen that operates on a SCADA client.
(2) Supervisory Control System The supervisory control system collects signal data on the process and sends control commands to the process. It is configured by a PLC (Programmable Logic Controller) or the like.
(3) Remote Input Output (RIO)
The remote input/output device connects with sensors installed in the process, converts the sensor signals into digital data, and sends the digital data to the supervisory control system.
(4) Communication infrastructure The communication infrastructure connects the supervisory control system and remote input/output devices.

Japanese Patent Application Laid-Open No. 2017-27211

The SCADA client in Patent Document 1 operates on a high-performance computer capable of executing supervisory control logic. Moreover, when installing a plurality of SCADA clients, it is necessary to prepare high-performance computers for the number of SCADA clients, and to individually implement the monitoring control logic. Also, when the SCADA client has a multi-monitor configuration, it is necessary to implement monitoring control logic for each HMI screen displayed on the monitor. Therefore, cost reduction of SCADA HMI is desired.

In order to reduce the cost of SCADA HMI, the inventor of the present application developed a browser-based HMI subsystem. Web application that executes the monitoring control logic on the server eliminates the need to implement individual monitoring control logic on the client terminal (web terminal). The client terminal only needs to display the result of the monitoring control logic processed by the server on the web browser. Therefore, the client terminal can be a low-spec computer that can run a web browser. For example, it will be possible to monitor and control the system from a mobile device such as a tablet. According to this, a configuration in which a plurality of client terminals are connected to the server can be realized at low cost. A web terminal that does not include monitoring control logic is called a thin client.

However, in plant monitoring, it is necessary to process tens of thousands of PLC signals at high speed and reflect them on the HMI screen. Therefore, a faster browser-based HMI subsystem is desired.

The present invention was made to solve the above problems. SUMMARY OF THE INVENTION It is an object of the present invention to provide a SCADA web HMI server device that reduces the amount of data processing and speeds up signal processing.

In order to achieve the above object, the SCADA web HMI server device according to the present invention is configured as follows.

The SCADA Web HMI Server device connects to Human Machine Interface (HMI) terminals and Programmable Logic Controllers (PLCs). The HMI terminal executes at least one web browser that displays an HMI screen on which parts that display the state of the plant are arranged. The SCADA web HMI server device transmits update data for updating the state of the parts according to the PLC signal received from the PLC.

The SCADA Web HMI server device comprises at least one processor and memory for storing programs. The program, when executed by the at least one processor, causes the at least one processor to perform processing including the following processing.

The screen information management process stores screen information that associates the screen name of the HMI screen, the part name of the part arranged on the HMI screen, and the PLC signal name of the PLC signal that changes the state of the part. to manage.

The browser information management process manages browser information that associates the browser name of the web browser in execution with the screen name of the HMI screen displayed in the web browser in execution.

The changed PLC signal extraction process receives a plurality of PLC signals from the PLC, and extracts the changed PLC signal name and the changed PLC signal value of the PLC signal that has changed among the plurality of PLC signals.

The browser display update process extracts the screen name and the part name associated with the same PLC signal name as the changed PLC signal name from the screen information, and updates the browser associated with the extracted screen name from the browser information. name, and send the update data including the extracted part name and the changed PLC signal value to the running web browser corresponding to the extracted browser name.

In one preferred aspect, the screen information management process reads a first screen device list, a second screen device list, and a derivative device list. The first screen device list includes the first screen name of the first HMI screen, the first part name of the first part arranged on the first HMI screen, and the first PLC of the PLC signal that changes the state of the first part. This is information associated with a signal name. The second screen device list is information that associates at least the second screen name of the second HMI screen with the second part name of the second part arranged on the second HMI screen. The derived device list is information that associates the second part name with the first part name of the first part that affects the state of the second part.

Further, the screen information management process reads these device lists and adds first screen information, second screen information and additional screen information to the screen information. The first screen information is information that associates the first screen name, the first part name, and the first PLC signal name. The second screen information is information that associates at least the second screen name with the second part name. The additional screen information includes the name of the second screen, the name of the first part linked to the name of the second part via the derived device list, and the device list of the first screen associated with the name of the first part. This information associates the name of the first PLC signal with the name of the first PLC signal.

Further, the browser display update process, when the name of the changed PLC signal is the same as the name of the first PLC signal, sends the name of the first part and the name of the changed PLC to the running web browser displaying the second HMI screen. and transmitting the updated data including signal values.

Additionally, the running web browser displaying the second HMI screen receives the update data including the changed PLC signal value of the first PLC signal that changes the state of the first part. Then, the running web browser inputs the changed PLC signal value of the first PLC signal to a predetermined script regarding the state change of the second part, and based on the calculation result of the script, the second part change the state of

According to the present invention, the SCADA web HMI server device transmits update data only to the running web browser displaying the HMI screen on which the parts corresponding to the changed PLC signal are arranged. That is, the HMI server device 10 may perform signal processing only on PLC signals that have changed among the received PLC signals. Therefore, the amount of data processing can be greatly reduced. Also, the update data is transmitted per web browser, not per HMI terminal. Therefore, when multiple web browsers are running on one HMI terminal, the update data is sent only to the running web browser displaying the HMI screen on which the parts related to the update data are arranged. As a result, the data processing amount of the HMI terminal can be reduced without being processed by the web browser that is not related to the update data.

According to the present invention, it is possible to reduce the cost by making the HMI subsystem a web application and increase the speed by reducing the amount of data processing.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure for demonstrating the system configuration|structure of SCADA in Embodiment 1 of this invention. 1 is a block diagram for explaining the configuration of a SCADA web HMI server device according to Embodiment 1 of the present invention; FIG. FIG. 4 is a diagram showing an example of a device list read into the SCADA web HMI server device according to Embodiment 1 of the present invention; FIG. 4 is a diagram for explaining an example of signal processing of the SCADA web HMI server device according to Embodiment 1 of the present invention; FIG. 4 is a block diagram for explaining the configuration of a SCADA web HMI server device according to Embodiment 2 of the present invention; FIG. 10 is a diagram showing an example of a device list and derived device list read into the SCADA Web HMI server device according to Embodiment 2 of the present invention; FIG. 9 is a diagram for explaining an example of signal processing of the SCADA web HMI server device according to Embodiment 2 of the present invention; 3 is a block diagram showing a hardware configuration example of an HMI terminal and a web HMI server; FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, when referring to the number, quantity, amount, range, etc. of each element in the embodiments shown below, unless otherwise specified or clearly specified by the number in principle, the reference The present invention is not limited to this number. Also, the structures and the like described in the embodiments shown below are not necessarily essential to the present invention unless otherwise specified or clearly specified in principle. Elements that are common in each drawing are denoted by the same reference numerals, and overlapping descriptions are omitted.

Embodiment 1.
<Overall composition>
FIG. 1 is a diagram for explaining the SCADA system configuration. The SCADA includes a human machine interface (HMI) 1, a programmable logic controller (PLC) 2 as a supervisory control system, a communication device 3 as a communication base, and an RIO 4 as subsystems. SCADA connects to monitored device 5 via PLC 2 or RIO 4 .

Descriptions of the PLC 2 (monitoring control system), the communication device 3 (communication infrastructure), and the RIO 4 are omitted because they are the same as those described in the background art. The monitoring target device 5 is a sensor, an actuator, or the like that constitutes a plant to be monitored and controlled.

The HMI 1 (SCADA web HMI system) includes a SCADA web HMI server device 10 (hereinafter referred to as HMI server device 10 ) and at least one HMI terminal 20 .

The HMI server device 10 connects to the PLC 2 via a computer network. The HMI server device 10 connects to the HMI terminal 20 via a computer network. The HMI server device 10 may be connected to multiple HMI terminals 20 . When there is no need to distinguish each HMI terminal, it is simply referred to as HMI terminal 20 .

The HMI terminal 20 is a thin client that does not include monitoring control logic and executes at least one web browser 21 . The web browser 21 displays an HMI screen on which parts that display the state of the plant are arranged. Specifically, the HMI terminal 20 comprises at least one monitor (display 20e in FIG. 8). One web browser 21 is displayed in full screen on one monitor. When the HMI terminal 20 has multiple monitors, the web browser 21 is displayed in full screen on each monitor. That is, the HMI terminal 20 runs multiple web browsers 21 .

HMI server device 10 executes HMI server application 11 . The HMI server application 11 has a web server function that communicates with the HMI terminal 20 and an I/O server function (application server function) that communicates with the PLC 2 . The HMI terminal 20 runs a web browser 21 . HMI 1, which is an execution environment, operates as a web application in which a script (for example, JavaScript (registered trademark)) operating on web browser 21 and HMI server application 11 cooperate.

The HMI server device 10 transmits update data for updating the state of parts to the web browser 21 according to the PLC signal received from the PLC 2 . The HMI server device 10 receives control commands from the web browser 21 and transmits them to the PLC 2 .

<SCADA Web HMI server device>
Characteristic processing of the HMI server application 11 that operates on the HMI server device 10 according to the first embodiment will be described with reference to the examples shown in FIGS.

In FIG. 2, the HMI server device 10 connects to an HMI terminal A (20A) and an HMI terminal B (20B). HMI terminal A comprises a first monitor and a second monitor. HMI terminal B is equipped with a third monitor. The browser A1 (21a1) is displayed in full screen on the first monitor. The browser A2 (21a2) is displayed in full screen on the second monitor. The browser B1 (21b1) is displayed in full screen on the third monitor. In FIG. 2, the browser A1 displays the HMI screen G1, the browser A2 displays the HMI screen G2, and the browser B1 displays the HMI screen G3. can be changed freely. When there is no need to distinguish each web browser, it is simply referred to as web browser 21 .

The HMI server device 10 includes at least one processor 10a and a program storage 10b, as shown in FIG. 8, which will be described later. The program is executed by the processor 10a to cause the processor 10a to execute the following processes.

When the HMI server application 11 starts, it creates a communication object for communicating with the web browser 21 and a communication object for communicating with the PLC.

Also, the HMI server application 11 reads the screen data 31 of the HMI screen on which the parts are arranged and the device list 32 at its start.

The screen data 31 is vector data defined for each HMI screen. As an example, the vector data is data in Scalable Vector Graphics (SVG) format. The SVG data includes the name, shape, position, color, and size of parts arranged on the HMI screen as attributes of the SVG elements. The file name of the screen data 31 includes the screen name.

The device list 32 is data defined for each HMI screen. As an example, this data is data in Comma-Separated Values (CSV) format. The device list 32 includes fields of part name (item name), type, comment, output PLC ID, PLC address, and communication address (FIG. 3). A part name is, for example, a combination of a screen name and a device number within the screen. Further, the name may be a combination of parts types. Each part name is a unique name in HMI1. Note that the file name of the device list 32 includes the screen name.

The HMI server application 11 also generates content for each HMI screen based on the read screen data 31 and device list 32 . Content includes SVG data and screen information. The HMI server application 11 transmits content corresponding to the HMI screen requested by the web browser 21 to the web browser 21 . The web browser 21 receives the content and displays the HMI screen.

HMI server application 11 stores the PLC signal received from PLC 2 in PLC signal state information 17 . The PLC signal state information 17 stores information that associates the PLC signal name of the received PLC signal with the PLC signal value. A PLC signal name is, for example, a name obtained by combining an output PLC ID and a PLC address in FIG. Each PLC signal name is a unique name in HMI1.

The screen information management processing 12 manages screen information 13 that associates the screen name of the HMI screen, the part name of the part arranged on the HMI screen, and the PLC signal name of the PLC signal that changes the state of the part. do.

The screen information 13 is generated based on the device list 32 defined for each HMI screen. FIG. 3 shows, as examples of the device list 32, a G1 device list 32a of the HMI screen G1, a G2 device list 32b of the HMI screen G2, and a G3 device list 32c of the HMI screen G3. FIG. 3 shows screen information 13 generated based on these device lists.

The browser information management processing 14 manages browser information 15 that associates the browser name of the web browser 21 in execution with the screen name of the HMI screen displayed in the web browser 21 in execution. In other words, the displayed HMI screen is managed in units of browsers (units of monitors), not in units of HMI terminals. A browser name is a combination of an HMI terminal name and a monitor number (browser number). Each browser name is a unique name in HMI1.

In FIG. 2, the browser information management process 14 includes, as the browser information 15, information that associates the browser name (A1) of the running web browser 21a1 with the screen name (G1), and the browser name (A2) of the running web browser 21a2. ) and the screen name (G2), and information that associates the browser name (B1) of the running web browser 21b1 with the screen name (G3).

The browser information 15 is updated, for example, when the web browser 21 is activated, when the web browser 21 is terminated, and when the HMI screen displayed on the web browser 21 transitions to another HMI screen.

A changed PLC signal extraction process 16 receives a plurality of PLC signals from the PLC 2, and extracts the signal name (changed PLC signal name) and signal value (changed PLC signal value) of the PLC signal that has changed among the plurality of PLC signals. do.

Specifically, the changing PLC signal extraction processing 16 compares the value of each PLC signal (previous value) stored in the PLC signal state information 17 with the value of each PLC signal received this time (current value). , to determine if there has been a change. If there is a change, the changed PLC signal extraction process 16 extracts the signal name (changed PLC signal name) and signal value (changed PLC signal value) of the changed PLC signal.

The browser display update process 18 extracts from the screen information 13 the screen name and part name associated with the same PLC signal name as the changed PLC signal name extracted by the changed PLC signal extraction process 16 .

Further, the browser display update process 18 extracts from the browser information 15 the browser name associated with the extracted screen name.

Further, the browser display update process 18 transmits update data including the extracted part name and the extracted changed PLC signal value to the running web browser 21 corresponding to the extracted browser name.

According to the browser display update process 18, the updated data to be transmitted is only the data about the PLC signal that has changed. Therefore, the amount of data is extremely small. Also, the update data is transmitted only to the running web browser 21 displaying the HMI screen on which the parts corresponding to the changed PLC signal are arranged. Therefore, updated data is not sent to web browsers that do not require updating.

<HMI terminal>
The running web browser 21 designated as the destination by the browser display update process 18 receives the update data. The web browser 21 changes the state (numerical value, color, shape, position) of the part corresponding to the part name included in the update data according to the changed PLC signal value.

When multiple web browsers are running on the HMI terminal 20, update data is processed only by the web browser 21 displaying the HMI screen on which the parts related to the update data are arranged. Therefore, the data processing amount of the HMI terminal 20 can be reduced without being processed by the web browser 21 unrelated to the update data. Due to the reduction in the amount of data processing, the HMI terminal 20 can be a computer with a low specification that allows the web browser 21 to operate. For example, it will be possible to monitor and control the system from a mobile device such as a tablet.

<Flow of signal processing>
The flow of signal processing in Embodiment 1 will be described with reference to the example shown in FIG.
FIG. 4 is a diagram for explaining the process of updating the state of the part G1_1 arranged on the screen G1 of the browser A1 according to the PLC signal P1_1 from the PLC2. P1_1 is a name combining the output PLC ID (P1) and the PLC address (1) in the G1 device list 32a of FIG.

In step S1, the changing PLC signal extraction process 16 receives a plurality of PLC signals (P1_1, P2_1, P3_1) from PLC2.

In step S2, the changing PLC signal extraction processing 16 compares the value of each PLC signal (previous value) stored in the PLC signal state information 17 with the value of each PLC signal received this time (current value), Determine if there has been a change. If there is a change, the changed PLC signal extraction process 16 extracts the changed PLC signal name and changed PLC signal value of the changed PLC signal. In the example of FIG. 4, the PLC signal that has changed is P1_1.

In step S3, the HMI server application 11 updates the PLC signal value corresponding to the PLC signal name (P1_1) stored in the PLC signal state information 17 with the current value.

In step S4, the browser display update process 18 extracts from the screen information 13 the screen name (G1) and the part name (G1_1) associated with the same PLC signal name (P1_1) as the extracted changed PLC signal name.

In step S5, the browser display update process 18 extracts from the browser information 15 the browser name (A1) associated with the extracted screen name (G1).

In step S6, the browser display update processing 18 transfers the extracted part name (G1_1) and the extracted changed PLC signal value to the communication object communicating with the running web browser corresponding to the extracted browser name (A1). Send update data containing

In step S7, the updated data is sent to browser A1 via the communication object.

Browser A1 then receives the update data and changes the state of part G1_1 according to the changing PLC signal value. For example, the display color of the part G1_1 changes.

As described above, the HMI server device 10 according to Embodiment 1 transmits update data only to the active web browser 21 displaying the HMI screen on which the parts corresponding to the changed PLC signal are arranged. . That is, the HMI server device 10 may perform signal processing only on PLC signals that have changed among the received PLC signals. Therefore, the amount of data processing can be greatly reduced. Also, the update data is transmitted per web browser, not per HMI terminal. Therefore, when a plurality of web browsers 21 are executed on one HMI terminal, update data is sent only to the running web browser 21 displaying the HMI screen on which parts related to the update data are arranged. be. As a result, the data processing amount of the HMI terminal 20 can be reduced without being processed by the web browser 21 unrelated to the update data.

By the way, the processing when the web browser 21 is activated and when the HMI screen of the web browser 21 changes is as follows. First, when the web browser 21 is activated or when the HMI screen of the web browser 21 changes, the browser (for example, 21a1) sends the newly opened HMI screen information to the HMI server application 11. Based on this, the HMI Server application 11 updates browser information 15 . Next, the HMI server application 11 uses the screen information 13 to extract the PLC signals required for that HMI screen. Next, the HMI server application 11 acquires the value of the PLC signal required for the HMI screen from the PLC signal state information 17 and transmits it to the browser.

Embodiment 2.
Next, a second embodiment of the present invention will be described with reference to examples shown in FIGS. 5 to 7. FIG.
The HMI server device 10 in Embodiment 1 described above executes processing for transmitting update data only to the web browser 21 displaying the parts associated with the changed PLC signal. This process requires the screen information 13 described above. The screen information 13 is generated based on the device list 32 defined for each HMI screen. The device list 32 associates the screen name of the HMI screen, the part name (item name) of the part arranged on the HMI screen, and the PLC signal name of the PLC signal that directly changes the state of the part. Information. As a general rule, a unique part name defined in device list 32 is associated with a unique PLC signal name.

By the way, there are cases where the state of parts arranged on a certain HMI screen is affected by the states of parts arranged on other HMI screens. For example, when the signal value of the first PLC signal corresponding to the first part arranged on the first HMI screen satisfies a specific condition, the use state of the second part arranged on the second HMI screen is changed from disable to enable. valid). Such a process is important as a safety process that enhances the safety of parts operation.

In this case, the second part is placed on the second HMI screen, but the first part is not. Therefore, the device list of the second HMI screen on which the first part is not arranged does not include information that associates the first part name with the first PLC signal name. Also, it is the first part that is directly related to the first PLC signal and the second part is only indirectly related. Therefore, the device list on the second HMI screen does not include information that associates the second part name with the first PLC signal name. Therefore, the update data regarding the first part is not transmitted to the web browser displaying the second HMI screen on which the second part is arranged. Therefore, according to the configuration for speeding up described in Embodiment 1, there is a problem that the above-described safety processing cannot be realized.

In the second embodiment, a derivative device list is introduced so as to cope with such cases.

<SCADA Web HMI server device>
Characteristic processing of the HMI server application 11 operating in the HMI server device 10 according to the second embodiment will be described with reference to the examples shown in FIGS.

The configuration shown in FIG. 5 is the same as the configuration in FIG.

The screen information management processing 12a manages the screen information 13 that associates the screen name of the HMI screen, the part name of the part arranged on the HMI screen, and the PLC signal name of the PLC signal that changes the state of the part. do. A PLC signal name is, for example, a name obtained by combining an output PLC ID and a PLC address in FIG. Each PLC signal name is a unique name in HMI1.

The screen information 13 is generated based on a device list 32 and a derivative device list 33 defined for each screen. FIG. 6 shows, as an example of the device list 32, a G1 device list 32a of the HMI screen G1, a G2 device list 32b of the HMI screen G2, a G4 device list 32d of the HMI screen G4, and a derivative device list 33. FIG. 6 shows screen information 13 generated based on these device list 32 and derivative device list 33 .

A method of generating the screen information 13 based on the device list 32 and the derivative device list 33 will be described with reference to the example shown in FIG.

First, the screen information management processing 12a reads the first screen device list (G1 device list 32a, G2 device list 32b), the second screen device list (G4 device list 32d) and the derived device list 33. FIG.

The first screen device list includes the first screen name of the first HMI screen, the first part name of the first part arranged on the first HMI screen, and the first PLC signal name of the first PLC signal that changes the state of the first part. It consists of information associated with For example, the G1 device list 32a in FIG. 6 includes information that associates the first screen name (G1), the first part name (G1_1), and the first PLC signal name (P1_1). Here, the first PLC signal name corresponds to a name obtained by combining the output PLCID and the PLC address.

The second screen device list is composed of information that associates at least the second screen name of the second HMI screen with the second part name of the second part arranged on the second HMI screen. Preferably, the second screen device list includes, like the first screen device list, the second screen name of the second HMI screen, the second part name of the second part arranged on the second HMI screen, and the name of the second part. It is composed of information associated with the second PLC signal name of the second PLC signal whose state is to be changed. Here, the second PLC signal name corresponds to a name obtained by combining the output PLCID and the PLC address.

For example, the G4 device list 32d in FIG. 6 includes information that associates the second screen name (G4), the second parts name (G4_1), and the second PLC signal name (P4_1). Here, the second PLC signal name corresponds to a name obtained by combining the output PLCID and the PLC address.

The derived device list 33 is link information that links information in one device list 32 and information in another device list 32 . The derived device list 33 is information that associates the name of the second part with the name of the first part that affects the state of the second part. Information linking such parts is not included in the second screen device list. In the example of FIG. 6, the derived device list 33 includes information that associates the second part name (G4_1) with the first part name (G1_1). Note that the file name of the derivative device list 33 includes the screen name.

The screen information management processing 12a adds the first screen information, the second screen information and the additional screen information to the screen information 13 by reading the device list 32 and the derivative device list 33. FIG.

The first screen information is information that associates the above-described first screen name, first part name, and first PLC signal name.

The second screen information is information that associates at least the second screen name and the second part name described above. Preferably, the second screen information is information that associates the name of the second screen, the name of the second part, and the name of the second PLC signal, similarly to the information of the first screen.

The additional screen information includes the second screen name defined in the second screen device list, the first part name linked to this second part name via the derivative device list 33, and the first part name associated with the first part name. This information is associated with the first PLC signal name in the screen device list. In FIG. 6, the screen information 13 includes the second screen name (G4) of the G4 device list 32d, the first part name (G1_1) linked to the second part name (G4_1) via the derived device list 33, and the second screen name (G4_1). It includes additional screen information associated with the first PLC signal name (P1_1) of the G1 device list 32a associated with the one part name (G1_1).

In this way, the screen information management processing 12a uses the derivative device list 33 to transfer the information of the first part (G1_1) that affects the state of the second part (G4_1) of the second HMI screen (G4) to the first screen device. Copy from the list (G1 device list 32a).

The browser display update process 18 extracts from the screen information 13 the screen name and part name associated with the same PLC signal name as the changed PLC signal name extracted by the changed PLC signal extraction process 16 .

Further, the browser display update process 18 extracts from the browser information 15 the browser name associated with the extracted screen name.

Further, the browser display update process 18 sends update data including the extracted part name and the extracted changed PLC signal value to the running web browser corresponding to the extracted browser name.

According to such processing, the browser display update processing 18 is executed by the running web browser ( B1) the updated data including the first part name (G1_1) and the changed PLC signal value.

<HMI terminal>
A running web browser (B1) displaying a second HMI screen (G4) receives update data including the changed PLC signal value of the first PLC signal (P1_1) that changes the state of the first part (P1_1). Then, the running web browser (B1) inputs the changed PLC signal value of the first PLC signal (P1_1) to a predetermined script regarding the state change of the second part (G4_1), and based on the calculation result of this script , changes the state of the second part (G4_1).

For example, in the script of the second part (G4_1), the change PLC signal value of the first PLC signal (P1_1) is a value indicating a specific browser name, and that value matches the browser name of the running web browser (G4). This is a program for changing the use state of the second part (G4_1) from disable to enable when the

The web browser being executed (A1) is the same as that of the first embodiment, so the explanation is omitted.

<Flow of signal processing>
The flow of signal processing in Embodiment 2 will be described with reference to the example shown in FIG.
FIG. 7 updates the state of the part G1_1 arranged on the screen G1 of the browser A1 and the use state of the part G4_1 arranged on the screen G4 of the browser B1 according to the PLC signal P1_1 from the PLC2. It is a figure for demonstrating the process which carries out. It is assumed that the part G1_1 and the part G1_2 arranged on the screen G1 are buttons capable of selecting only one of them, and the part G1_1 is selected.

In step S1, the changing PLC signal extraction process 16 receives a plurality of PLC signals (P1_1, P2_1, P3_1) from PLC2.

In step S2, the changing PLC signal extraction processing 16 compares the value of each PLC signal (previous value) stored in the PLC signal state information 17 with the value of each PLC signal received this time (current value), Determine if there has been a change. If there is a change, the changed PLC signal extraction process 16 extracts the changed PLC signal name and changed PLC signal value of the changed PLC signal. In the example of FIG. 7, the PLC signal that has changed is P1_1.

In step S3, the HMI server application 11 updates the PLC signal value corresponding to the PLC signal name (P1_1) stored in the PLC signal state information 17 with the current value.

In step S4, the browser display update processing 18 performs screen names (G1, G4) and part names (G1_1, G1_1) associated with the same PLC signal name (P1_1) as the extracted changed PLC signal name from the screen information 13. to extract

In step S5, the browser display update process 18 extracts from the browser information 15 the browser names (A1, B1) associated with the extracted screen names (G1, G4).

In step S6, the browser display update processing 18 transfers the extracted part name (G1_1) and the extracted changed PLC signal value to the communication object communicating with the running web browser corresponding to the extracted browser name (A1). Send update data containing

In step S7, the updated data is sent to the running web browser A1 via the communication object.

Browser A1 then receives the update data and changes the state of part G1_1 according to the changing PLC signal value. For example, the display color of the part G1_1 changes.

After the process of step S5, in step S8, the browser display update process 18 adds the extracted part name (G1_1) and and transmitting updated data including extracted changed PLC signal values.

In step S9, the updated data is sent to the running web browser (B1) via the communication object.

After that, the running web browser (B1) displaying the second HMI screen (G4) receives update data including the change PLC signal value of the first PLC signal (P1_1) that changes the state of the first part (P1_1). do.

Then, the running web browser (B1) inputs the changed PLC signal value of the first PLC signal (P1_1) into a predetermined script for the state change of the second part (G4_1). This script executes the second part ( G4_1) is a program that changes the use state from disable to enable.

The running web browser (B1) changes the state of the second part (G4_1) based on the calculation result of the script with the changed PLC signal value as the input value. In the example of FIG. 7, the unlocking condition is satisfied, and the use state of the second part (G4_1) changes from disable to enable.

As described above, according to the HMI server device 10 and the HMI terminal 20 according to the second embodiment, it is possible to change the state of parts within a certain HMI screen according to the state of parts within another screen. Therefore, according to the system of the second embodiment, it is possible to realize the above-described safe processing while adopting the configuration for speeding up described in the first embodiment. Further, by using the derived device list 33, the information of the linked device list can be copied and added to the screen information, so that the design work can be made more efficient.

<Hardware configuration example>
FIG. 8 is a block diagram showing a hardware configuration example of the HMI server device 10 and the HMI terminal 20. As shown in FIG.

Each process of the HMI server device 10 described above is implemented by a processing circuit. The processing circuit is configured by connecting a processor 10a, a memory 10b, and a network interface 10c. The processor 10a realizes each function of the HMI server device 10 by executing various programs stored in the memory 10b. The network interface 10c is a device that connects with the PLC 2 and the HMI terminal 20 via a computer network and can transmit and receive PLC signals and control commands.

Each process of the HMI terminal 20 described above is implemented by a processing circuit. The processing circuit is configured by connecting a processor 20a, a memory 20b, a network interface 20c, an input interface 20d, and at least one display 20e. The processor 20a realizes each function of the HMI terminal 20 by executing various programs stored in the memory 20b. The network interface 20c is a device capable of connecting to the HMI server device 10 and transmitting/receiving PLC signals and control commands. The input interface 20d is an input device such as a keyboard, mouse, touch panel, or the like. A plurality of displays 20e may be provided. Note that the HMI terminal 20 may be a mobile terminal such as a tablet.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

1 HMIs
2 PLCs
3 communication device 4 RIO
5 Monitored device 10 HMI server device 10a Processor 10b Memory 10c Network interface 11 HMI server applications 12, 12a Screen information management processing 13 Screen information 14 Browser information management processing 15 Browser information 16 Changing PLC signal extraction processing 17 PLC signal state information 18 Browser Display update processing 20, 20A, 20B HMI terminal 20a Processor 20b Memory 20c Network interface 20d Input interface 20e Displays 21, 21a1, 21a2, 21b1 Web browser 31 Screen data 32, 32a, 32b, 32c, 32d Device list 33 Derived device list

Claims (3)

Connected to an HMI terminal executing at least one web browser displaying a human machine interface (HMI) screen on which parts displaying the plant status are arranged, and a programmable logic controller (PLC), the PLC received from the PLC. In a SCADA web HMI server device that transmits update data for updating the state of the part in response to a signal,
at least one processor;
a memory for storing a program;
The program is executed by the at least one processor, causing the at least one processor to:
Screen information management processing for managing screen information that associates the screen name of the HMI screen, the part name of the part arranged on the HMI screen, and the PLC signal name of the PLC signal that changes the state of the part. and,
browser information management processing for managing browser information that associates the browser name of the running web browser with the screen name of the HMI screen displayed on the running web browser;
a changed PLC signal extraction process of receiving a plurality of PLC signals from the PLC and extracting a changed PLC signal name and a changed PLC signal value of a PLC signal that has changed among the plurality of PLC signals;
extracting the screen name and the part name associated with the same PLC signal name as the changing PLC signal name from the screen information, extracting the browser name associated with the extracted screen name from the browser information; browser display update processing of transmitting the update data including the extracted part name and the changed PLC signal value to the running web browser corresponding to the extracted browser name. A SCADA Web HMI server device characterized by: The screen information management process includes:
A first screen name of a first HMI screen, a first part name of a first part arranged on the first HMI screen, and a first PLC signal name of a first PLC signal that changes the state of the first part are associated with each other. 1 screen device list,
a second screen device list that associates at least second screen names of second HMI screens with second part names of second parts arranged on the second HMI screen;
reading a derived device list that associates the second part name with the first part name of the first part that affects the state of the second part,
In the screen information,
the name of the second screen, the name of the first part linked to the name of the second part via the derived device list, and the name of the first PLC signal in the device list of the first screen associated with the name of the first part , additional screen information associated with , and
In the browser display update process, when the changed PLC signal name is the same as the first PLC signal name, the first part name and the changed PLC signal value are sent to the running web browser displaying the second HMI screen. transmitting the update data comprising
The SCADA web HMI server device according to claim 1, characterized by: The running web browser displaying the second HMI screen,
receiving the update data including the changed PLC signal value of the first PLC signal that changes the state of the first part;
inputting the changed PLC signal value of the first PLC signal into a predetermined script for changing the state of the second part, and changing the state of the second part based on the calculation result of the script;
3. The SCADA web HMI server device according to claim 2, characterized by:

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