TW201704910A - Plant control system - Google Patents

Abstract

There is provided a plant control system capable of increasing the number of TAGs and achieving a single-shot output. A server machine includes a single-shot output function unit and a SCADA server unit. The SCADA server unit manages TAGs of a SCADA, and outputs an I/O TAG associated with an I/O TAG title according to a signal output from the single-shot output function unit. The single-shot output function unit receives the I/O TAG title transmitted from a client machine, and outputs an ON signal for transmitting a control I/O TAG corresponding to the I/O TAG title to the SCADA server unit at the start of measurement of a certain time. Then, at the end of the measurement of the certain time, an OFF signal for transmitting an erase I/O TAG for erasing the control I/O TAG is output to the SCADA server unit.

Description

Factory control system

The present invention relates to a plant control system for performing plant control.

In conventional plant control systems, the plant is controlled by a Programmable Logic Controller. The programmable logic controller is connected to a monitoring control device including an HMI (Human Machine Interface) via a monitoring control device ‧ an inter-controller network (scanning transmission device). The programmable logic controller and the monitoring control device transmit data to each other.

Here, the monitoring control device uses SCADA (Supervisory Control And Data Acquisition). In the SCADA, a plurality of monitoring screens are created. In addition, an internal TAG (a tag that does not communicate with a programmable logic controller) is used as an internal signal in SCADA. In addition, in SCADA, an I/OTAG (Input/Output TAG) (a tag that communicates with a programmable logic controller) is used as a signal for transmission with a programmable logic controller. There is an upper limit to the number of TAGs a SCADA can use. Therefore, if the TAG used as the internal TAG is increased, the TAG that can be used as the I/OTAG is used. It will be reduced.

In such a plant control system, there is a case where the plant is controlled from the monitoring control device. At this time, the operator presses the control operation button or the like displayed on the SCADA. Thereby, the I/OTAG corresponding to the control operation button or the like is selected. Then, press the OK button of the execution button or the like. Thereby, the selected I/OTAG is turned ON. The ON state I/OTAG is transferred to the programmable logic controller.

If the ON state is directly controlled by the monitoring control device and the inter-controller network, the selected I/OTAG will not reach the programmable logic controller due to the disconnection of the monitoring control device, the network between the controllers, and the like. The situation. At this time, the programmable logic controller may erroneously determine that the selected I/OTAG has turned OFF (for example, the program of the programmable logic controller is designed to be determined to be in an ON state by continuously receiving the I/OTAG). . In order to prevent this erroneous determination, the programmable logic controller normally detects the change of the selected I/OTAG and maintains the ON state of the selected I/OTAG.

Here, the I/OTAG system that is kept in the ON state must be turned OFF before the operation of the next control operation button or the like. In the method of turning off the I/O TAG, a program for issuing an instruction to turn off the selected I/O TAG after a certain period of time is executed in the SCADA, and the command signal is output to the programmable logic control. Device. As described above, the command signal output that is turned OFF after a certain period of time has elapsed since the I/O TAG is turned on is referred to as a single shot output.

In the above configuration, in order to prevent malfunction, control When the operation button is pressed, it waits until the OK button is pressed to perform control. Therefore, in order to maintain the selected I/OTAG within SCADA, each control action button must have an internal TAG. In addition, each control operation button must also have an internal TAG for the counter that determines that the button is pressed as a reference to measure a certain time. Therefore, if the number of control operation buttons and the like is increased, the number of internal TAGs is greatly increased. In addition, the control program will also increase. Therefore, there is a problem that a single output requires a large number of programs and internal TAGs. Further, with the above problems, there is a problem that the performance of the SCADA is deteriorated, the reliability is lowered due to a program error, and the amount of work when the signal is increased and deleted is increased. In addition, due to the limited number of TAGs, there is also a problem of insufficient internal TAG in large systems.

In order to solve the above problems, various proposals have appeared. For example, there has been proposed a plant control system capable of performing single-shot output without adding a program for signal transmission to a monitoring control device and a programmable logic controller (Patent Document 1 below). The plant control system has a single-output function unit for the SCADA of the programmable logic controller connected to the control factory, and the selected plant control content (by the respective control operation buttons) After the corresponding control signal (control I/OTAG) is sent to the programmable logic controller, the cancellation signal (cancellation I/OTAG) for canceling the control signal held by the programmable logic controller is sent to the programmable logic controller, and the The single-output function unit is configured to be external to SCADA and external to the programmable logic controller.

According to the factory control system of Patent Document 1, it is possible to realize the TAG (without adding an internal TAG) without using an I/OTAG. Single output, so a large number of TAGs can be used for I/OTAG.

(previous technical literature) (Patent Literature)

Patent Document 1: International Patent Publication No. 2011/036799

However, in the factory control system described in Patent Document 1, since the SCADA directly transfers data to and from the programmable logic controller, the upper limit of the number of TAGs that can be processed by the entire plant control system is one for the SCADA. The number of TAGs. Further, since the SCADA of each monitoring control device manages the TAGs, it is necessary to update all the SCADA data every time the TAG is changed in a large factory with a large number of SCADA stations. Therefore, there is a problem of an increase in the amount of data management operations. In addition, the monitoring control device that does not implement the TAG update performs monitoring and control of the factory with the old TAG data. Therefore, there is a problem that the product is damaged or the size is different from the requirement due to the control of the wrong control data. In addition, misuse of old TAG data may also cause abnormal equipment in the factory.

The present invention has been made in order to solve the above problems, and an object of the present invention is to provide a plant control system capable of amplifying the number of TAGs. In addition, there is a factory control system that can realize a single-output without requiring a program for signal transmission between the monitoring control device and the programmable logic controller without using a TAG other than the I/OTAG.

In order to achieve the above object, the plant control system of the present invention has the following configuration. The factory control system has a user terminal, a servo terminal and a programmable logic controller. The programmable logic controller is controlled by the user terminal as the monitoring control device and the servo terminal.

The client machine has a SCADA client that sends an I/OTAG name corresponding to the factory control content selected by the operator.

The servo end system has a single output function unit and a SCADA servo end unit. The single output function is set outside the SCADA servo end. The single-output function unit receives the I/OTAG name sent from the SCADA client. The SCADA servo end manages the TAG of the SCADA and outputs the I/OTAG associated with the I/OTAG name corresponding to the signal output from the single output function.

The programmable logic controller controls the factory based on the I/OTAG output from the SCADA servo end.

The client machine, the server terminal, and the programmable logic controller are connected via a network device. Specifically, the SCADA client of the client is connected to the single-output function of the server via the network of the monitoring control device. The single-output function unit is connected to the SCADA servo end inside the servo unit. The SCADA servo end is connected to the programmable logic controller via a monitoring control device ‧ inter-controller network.

The single-output function unit includes a memory unit, a timer counting unit, and an output unit. Memory of memory is sent from the SCADA client The name of the I/OTAG sent. In addition, when the server is connected to a plurality of subscribers, the single-output function unit has a memory unit for each SCADA client end of the subscriber.

The timer counting unit starts measurement of a predetermined time set in advance when the control content is executed at the SCADA user end.

The output unit outputs an ON signal for transmitting the control I/OTAG corresponding to the I/OTAG name stored in the memory unit to the SCADA servo end when the measurement is started for a certain period of time. Thereafter, the output unit outputs an OFF signal for canceling the I/OTAG transmission of the control I/OTAG to the SCADA servo end when the measurement is completed for a certain period of time.

According to the present invention, the SCADA is separated into a SCADA server that manages the TAG of the SCADA, and the SCADA client that constitutes the operation screen, and the management of the TAG is simplified at the SCADA server. Therefore, the number of TAGs can be amplified by setting a plurality of SCADA servos. In addition, according to the present invention, in the configuration in which the SCADA is separated into the SCADA servo terminal and the SCADA client terminal, they do not interfere with each other, and there is no need to attach a program for signal transmission between the monitoring control device and the programmable logic controller, and it is not necessary to use A TAG other than I/OTAG can achieve single-output.

1‧‧‧Monitoring Control Unit (HMIC1)

2, 4‧‧‧SCADA client

3‧‧‧Monitoring Control Unit (HMIC2)

5‧‧‧Monitoring Control Unit (HMIS1)

6, 8‧‧‧SCADA server

7‧‧‧Monitoring Control Unit (HMIS2)

11, 21‧‧‧ Picture A

12, 22‧‧‧ Clear button

13, 23‧‧‧ Execution button

14, 24‧‧‧Control operation button A

15, 25‧‧‧Control operation button B

20, 30‧‧‧I/OTAG Storage

31‧‧‧Monitoring control unit ‧inter-controller network

32‧‧‧Monitoring control device network

41‧‧‧Programmable Logic Controller

51, 52‧‧‧ single output function

60, 80‧‧‧ Memory Department

61‧‧‧HMIC1 memory unit

62, 72‧‧‧Memory A

63, 73‧‧‧Memory Department B

64, 74‧‧‧ Memory Department n

65, 85‧‧‧Timer counting section

66‧‧‧Timer counting section (for HMIC1)

71‧‧‧HMIC2 memory unit

76‧‧‧Timer counting section (for HMIC2)

81, 82‧‧‧ Output Department

91‧‧‧ Memory status of the I/OTAG name corresponding to the control operation button A of the monitoring control unit (HMIC1) 1.

92‧‧‧Memory status of the I/OTAG name corresponding to the control operation button B of the monitoring control unit (HMIC1)1

93‧‧‧ Memory status of the I/OTAG name corresponding to the control operation button A of the monitoring control unit (HMIC2)

94‧‧‧Control operation button B with monitoring control unit (HMIC2) 3 Memory status of the corresponding I/OTAG name

95‧‧‧Timer value corresponding to the monitoring control unit (HMIC1)1

96‧‧‧Timer value corresponding to the monitoring control unit (HMIC2)3

97, 98‧‧‧ output signal

T1 to t11‧‧‧

Fig. 1 is a configuration diagram of a plant control system according to a first embodiment of the present invention.

Fig. 2 is a data path diagram for explaining the operation of the plant control system according to the first embodiment of the present invention.

Fig. 3 is a block diagram showing the details of the single-function function unit of the plant control system according to the first embodiment of the present invention.

Fig. 4 is a timing chart for explaining the operation of the plant control system according to the first embodiment of the present invention.

Fig. 5 is a configuration diagram of a plant control system according to a second embodiment of the present invention.

Embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same or corresponding components are denoted by the same reference numerals, and the repeated description is omitted or omitted.

Embodiment 1.

Fig. 1 is a configuration diagram of a plant control system according to a first embodiment of the present invention. The plant control system shown in Fig. 1 is controlled by a user terminal as a monitoring control device and a servo terminal to control a programmable logic controller. The monitoring control device (HMIC1) 1 is a customer terminal. The monitoring control device (HMIC2) 3 is a customer terminal. The monitoring control device (HMIS1) 5 is a servo terminal.

The monitoring control device (HMIC1) 1 uses the SCADA client 2. The screen A11 is displayed on the SCADA client 2. On this screen A11, buttons corresponding to various control contents of a factory (not shown) are arranged. Specifically, the control operation button A14 is placed on the screen A11. There are a plurality of control operation buttons. Specifically, in addition to controlling the operation button A14, a control operation button B15, ..., a control operation button n are provided (province Slightly illustrated). The control operation button A14 is composed of a manual button and an automatic button. The control operation button B15 is composed of a back button and a forward button. Further, a clear button 12 and an execution button 13 are also arranged on the screen A11.

Similarly, the monitoring control device (HMIC2) 3 uses the SCADA client 4. The SCADA client 4 can display a screen A21 on the same screen as the screen A11 of the SCADA client 2. A button corresponding to various control contents of a factory (not shown) is arranged on the screen A21. Specifically, the control operation button A24 is placed on the screen A21. There are a plurality of control operation buttons. Specifically, in addition to the control operation button A24, control operation buttons B25, ..., and control operation buttons n (not shown) are provided. Further, a clear button 22 and an execution button 23 are also arranged on the screen A21.

On the other hand, the monitoring control device (HMIS1) 5 uses the SCADA servo terminal 6. The SCADA servo 6 manages the TAG of the SCADA, and outputs an I/OTAG associated with the I/OTAG name in response to the signal output from the single-output function unit 51. The I/OTAG storage unit 20 is provided in the SCADA servo terminal 6. The I/OTAG is stored in the I/OTAG storage unit 20. This I/OTAG is used as a signal for transmission to the outside. Specifically, a bit signal, an analog signal, and the like are assigned to the I/OTAG system. The I/OTAG system also contains signals corresponding to factory control content. The number of I/OTAGs is limited. Further, an internal TAG storage unit (not shown) is provided in the SCADA servo terminal 6. The internal TAG is stored in the internal TAG storage unit. This internal TAG is used as an internal signal in the SCADA servo terminal 6. There is a limit to the number of internal TAGs.

The component symbol 32 is a network between the monitoring control devices. The monitoring control device inter-network 32 connects the monitoring control device (HMIC1) 1 to the monitoring control device (HMIC2) 3 and the monitoring control device (HMIS1) 5. In addition, in the first figure, the illustration of the wiring between the SCADA client 2 and the SCADA client 4 and the single-output function unit 51 in the monitoring control device (HMIS1) 5 is omitted. In order to improve the reliability, the monitoring control device (HMIS1) 5 can also be constructed by redundancy.

The component symbol 41 is a programmable logic controller. The programmable logic controller 41 is disposed outside the SCADA servo terminal 6. The programmable logic controller 41 has a function of controlling a factory (not shown) based on an I/O TAG output from the SCADA servo terminal 6.

The component symbol 31 is a monitoring control device ‧ inter-controller network. The monitoring control device ‧ the inter-controller network 31 connects the I/O TAG storage unit 20 to the programmable logic controller 41. By this connection, the I/OTAG stored in the I/OTAG storage unit 20 can be output to the programmable logic controller 41.

In the monitoring control device (HMIS1) 5 of the present embodiment, the single-output function unit 51 is provided outside the SCADA servo terminal 6. The single-output function unit 51 has a function of transmitting and receiving data to and from the SCADA client 2 using a function for the SCADA client 2. Similarly, the function of the SCADA client 4 is used to transfer data to and from the SCADA client 4. Further, the single-output function unit 51 has a function of outputting the I/OTAG storage unit 20 of the SCADA servo unit 6. Specifically, the single-output function unit 51 includes a storage unit 60, The timer counting unit 65 and the output unit 81.

The memory unit 60 memorizes the I/OTAG name transmitted from the SCADA client 2 or the SCADA client 4. The timer counting unit 65 starts measurement of a predetermined time set in advance when the SCADA client 2 or the SCADA client 4 performs an operation of controlling the content. The output unit 81 outputs an ON signal for transmitting the control I/OTAG corresponding to the I/OTAG name stored in the memory unit 60 to the SCADA servo terminal 6 at the start of measurement at a predetermined time. Thereafter, the output unit 81 outputs an OFF signal for canceling the I/OTAG transmission of the control I/OTAG to the SCADA servo terminal 6 when the measurement is completed for a predetermined period of time.

Here, in the second drawing, the SCADA client 2 is taken as an example, and the transfer of data between the functions will be described. Fig. 2 is a data path diagram for explaining the operation of the plant control system according to the first embodiment of the present invention.

The SCADA client 2 of the client is connected to the single-output function unit 51 of the server via the monitoring control device network 32. The single-output function unit 51 is connected to the SCADA servo terminal 6 inside the servo terminal. The SCADA servo terminal 6 is connected to the programmable logic controller 41 via the monitor control device ‧ the inter-controller network 31.

The SCADA client 2 transmits an I/OTAG name corresponding to the factory control content selected by the operator. The SCADA client 2 describes a function for outputting an I/OTAG name or the like when the control operation button A14 is pressed. Specifically, when the control operation button A14 is pressed, a letter regarding a symbol such as an I/OTAG name corresponding to the control operation button A14 is transmitted. number. The single-output function unit 51 of the monitoring control device (HMIS1) 5 receives the signal regarding the I/OTAG name transmitted from the SCADA client 2, and memorizes the I/OTAG name in the storage unit 60.

At this time, when the I/OTAG name is not stored in the storage unit 60, the I/OTAG name is stored in the storage unit 60. On the other hand, when the I/OTAG name is already stored in the storage unit 60, the memory of the I/OTAG name is erased from the storage unit 60. Thereby, the selection of the control operation button A14 can be released by pressing the control operation button A14 again.

Further, in the SCADA client terminal 2, the corresponding control operation button A14 also describes a function for responding whether or not the I/OTAG name has been memorized in the storage unit 60. Specifically, the name plate ("manual" and "automatic") of the control operation button A14 or the like corresponding to the I/OTAG name stored in the memory unit 60 is blinked or the control operation button A14 is changed to the concave state. Thereby, the operator who operates the SCADA client 2 clearly indicates the selection status of the control operation button A14 or the like.

Further, in the SCADA client 2, two functions are described corresponding to the execution button 13. These functions are composed of the eraser regarding the I/OTAG name memorized in the memory unit 60, and the initiator of the timer counting unit 65. Specifically, when the SCADA client 2 performs a predetermined execution operation, the I/OTAG name memorized in the memory unit 60 is erased. At the same time, the timer counting unit 65 starts the measurement of the timer setting time which is set in advance as a predetermined time. Further, this function is also set to be transmitted to the timer counting unit 65 by using the timer setting time as a factor.

Further, in the SCADA client 2, a function for erasing the I/OTAG name stored in the storage unit 60 is described corresponding to the clear button 12. Specifically, when the clear button 12 is pressed, the I/OTAG name memorized in the memory unit 60 is erased.

Since there are a plurality of monitoring and control devices, the single-output function for supporting a plurality of monitoring and control devices will be described with reference to FIG. Fig. 3 is a block diagram showing the details of the single-function function unit of the plant control system according to the first embodiment of the present invention.

The single-output function unit 51 is composed of a storage unit 60, a timer counting unit 65, and an output unit 81. The memory unit 60 is provided with a memory unit for controlling an operation button (for the HMIC 1) 61, a memory unit for controlling the operation button (for the HMIC 2) 71, ..., a memory unit for controlling the operation button (for HMICn) (omitted from the figure) Show). Further, the control operation button memory unit (for the HMIC 1) 61 is provided with a control operation button memory unit A62, a control operation button memory unit B63, and a control operation button memory unit n64. Similarly, the control operation button memory unit (for HMIC 2) 71 is provided with a control operation button memory unit A72, a control operation button memory unit B73, and a control operation button memory unit n74.

The timer counting unit 65 is provided with a timer counting unit (for the HMIC 1) 66, a timer counting unit (for the HMIC 2) 76, a timer counting unit (for HMICn) (not shown).

Next, the operation of the plant control system will be described using FIG. Fig. 4 is a timing chart for explaining the operation of the plant control system according to the embodiment of the present invention.

In Fig. 4, the horizontal axis represents time. The component symbol 91 is a memory state of the I/OTAG name corresponding to the control operation button A of the monitoring control device (HMIC1) 1. The component symbol 92 is a memory state of the I/OTAG name corresponding to the control operation button B of the monitoring control device (HMIC1) 1. The component symbol 93 is a memory state of the I/OTAG name corresponding to the control operation button A of the monitoring control device (HMIC2) 3. The component symbol 94 is a memory state of the I/OTAG name corresponding to the control operation button B of the monitoring control device (HMIC2) 3. The component symbol 95 is a timer value corresponding to the monitoring control device (HMIC1) 1. The component symbol 96 is a timer value corresponding to the monitoring control device (HMIC2) 3. The component symbols 97 and 98 are output signals. Specifically, the output signal 97 is output from the output unit 81 in response to the control operation button A14. The output signal 98 is output from the output unit 81 in response to the control operation button B15.

In Fig. 4, when the operation is performed from the monitoring control device (HMIC1) 1, the I/OTAG names corresponding to the control operation button A14 and the control operation button B15 are memorized to the memory unit A62 and the memory unit A63 in accordance with the operation sequence. That is, at time t _1, when the monitoring control means (HMIC1) 1 A14 Control operation button is pressed, as shown in memory state, and controls the operation button corresponding to A14 I / OTAG name to the memory storage unit would A62 91.

At time t ₂ after time t ₁ , when the control operation button B25 is pressed in the monitoring control device (HMIC2) 3, as indicated by the memory state 94, the I/OTAG name corresponding to the control operation button B25 is memorized to the memory unit. B72.

Time after time t ₂ t _3, when the monitoring control means (HMIC1) in an execution button 13 is depressed, then the control erasing operation button corresponding to A14 I / OTAG name in the memory section A62. Further, at the same time, the timer in the timer counting unit 66 is started.

Next, the value of the timer 95 until the timer reaches the set time (time t ₅ reaches up) period, the output unit 81 based on the synchronization with the respective memories of all of the I to the memory unit A62 of the memory portion n64 / OTAG name In the case of a corresponding signal output 97 or the like, an ON signal is output. When the input of the ON signal is obtained, the I/OTAG storage unit 20 outputs the control I/O TAG corresponding to the ON signal to the programmable logic controller 41 via the monitoring control unit ‧ the inter-controller network 31. Thereby, it is possible to control the state of the factory with the control contents of all the control I/OTAGs corresponding to the output signal 97.

At time t after time t _{3. 4,} in this state, when performing the monitoring control device 3 (HMIC2) button 23 is pressed, control will be erased and the operation button B25 corresponding I / OTAG name in the memory section A72. Further, at the same time, in the timer counting unit 76, the timer is started.

Next, the value of the timer 96 until the timer reaches the set time (arrival time t ₈₎ of the period, the output unit 81 based on the synchronization with the respective memories of all of the I to the memory unit A72 of the memory portion n74 / OTAG name In the case of a corresponding signal output 98 or the like, an ON signal is output. When the input of the ON signal is obtained, the I/OTAG storage unit 20 outputs the control I/O TAG corresponding to the ON signal to the programmable logic controller 41 via the monitoring control unit ‧ the inter-controller network 31. Thereby, it is possible to control the state of the factory with the control contents of all the control I/OTAGs corresponding to the output signal 98.

At the time t ₅ after the time t ₄ , when the timer value 95 reaches the timer set time, the output unit 81 sets the output signal 97 and the like as OFF signals and simultaneously outputs them. When the input of the output signal 97 or the like which is turned OFF is obtained, the I/OTAG storage unit 20 outputs all of the erase I/O TAGs corresponding to the output signal 97 and the like to the programmable logic controller 41. As a result, the factory is in a state of stopping control due to the control content of the control I/OTAG corresponding to each of the output signal 97 and the like.

Further, at time t ₈ after time t ₇ , when the timer value 96 reaches the timer set time, the output unit 81 sets the output signal 98 and the like as OFF signals and outputs them simultaneously. When the input of the output signal 98 or the like which is turned OFF is obtained, the I/OTAG storage unit 20 outputs all the erase I/O TAGs corresponding to the output signal 98 and the like to the programmable logic controller 41. As a result, the factory is in a state of stopping control due to the control content of the control I/OTAG corresponding to each of the output signal 98 and the like.

At time point after ₅ t t _6, when the monitoring control means (HMIC2) controls the operation button 3 is depressed A24, as shown in memory state, and controls the operation button corresponding to A24 I / OTAG name to the memory portion of memory 93 will A72.

Further, time after time t ₆ t _7, when the monitoring control means (HMIC1) 1 A14 Control operation button is pressed, as shown in memory state, and controls the operation button corresponding to A14 I / OTAG name memory 91 will again To the memory unit A62.

At the time t ₉ after the time t ₈ , in the above state, when the clear button 22 is pressed by the monitoring control device (HMIC 2) 3, all of the memories memorized by the memory unit A72 to the memory unit n74 of the memory unit 71 of the HMIC 2 are pressed. The I/OTAG name is also removed. Therefore, the control I/OTAG corresponding to the output signal 97 is not output in the I/OTAG storage unit 20. In other words, the factory maintains the state of stopping control due to the control content of the control I/OTAG corresponding to each of the output signal 97 and the like.

Time after time t ₉ t _10, when the monitoring control means (HMIC1) in an execution button 13 is depressed, then the control erasing operation button corresponding to A14 I / OTAG name in the memory section A62. Further, at the same time, in the timer counting unit 66, the timer is started.

Next, the value of the timer 95 until the timer reaches the set time (arrival time t ₁₁₎ during the output unit 81 based on the synchronization with the respective memories of all of the I to the memory unit A62 of the memory portion n64 / OTAG name In the case of a corresponding signal output 97 or the like, an ON signal is output. When the input of the ON signal is obtained, the I/OTAG storage unit 20 outputs the control I/O TAG corresponding to the ON signal to the programmable logic controller 41 via the monitoring control device ‧ the inter-controller network 31. Thereby, it is possible to control the state of the factory again with the control contents of all the control I/OTAGs corresponding to the output signal 97.

Time after time t ₁₀ t _11, when the timer value of the timer 95 reaches the set time, the output unit 81 and the like put into an output signal 97 and simultaneously outputs an OFF signal. When the input of the output signal 97 or the like which is turned OFF is obtained, the I/OTAG storage unit 20 outputs all of the erase I/O TAGs corresponding to the output signal 97 and the like to the programmable logic controller 41. As a result, the factory returns to the state of the stop control again by controlling the control content of the I/OTAG corresponding to each of the output signal 97 and the like.

According to the plant control system of the first embodiment described above, SCADA is separated into a SCADA servo terminal that manages the TAG of SCADA, and a SCADA client that is configured by an operation screen, and the management of the TAG can be simplified at the SCADA server. Therefore, it is possible to support a large-scale factory that requires a large number of I/OTAGs by providing a plurality of SCADA servo terminals to amplify the number of TAGs. In addition, by means of a single-output function unit of a plurality of servo terminals, a single user terminal can monitor a large system as a whole.

Further, according to the plant control system of the first embodiment, the output unit 81 outputs the plurality of ON signals corresponding to each of the plurality of I/OTAG names operated from the plurality of monitoring control devices at the start of the measurement at a predetermined time. With the operation timing of each monitoring control device, the operation starts simultaneously without interference. Further, the output unit 81 outputs a plurality of OFF signals corresponding to each of the plurality of I/OTAG names at the same time as the operation timing of each of the plurality of I/OTAG names, and simultaneously outputs them without interference with each other. Since the I/OTAG can be output without using the internal TAG by using the I/OTAG name, the TAG of the SCADA servo 6 can be prevented from being enlarged. Further, the SC/A servo 6 and the I/F program of the programmable logic controller 41 are not complicated, and the plurality of control contents can be collectively executed without interfering with each other in accordance with the plurality of monitoring control devices. That is, the operability of the factory control is improved.

Embodiment 2.

Fig. 5 is a configuration diagram of a plant control system according to a second embodiment of the present invention. It is to be noted that the same or equivalent parts as those in the first embodiment are denoted by the same reference numerals, and their description is omitted. In addition, in FIG. 5, the single-output function unit 51 and the single-output function unit in the monitoring control device (HMIS2) 7 in the SCADA client 2 and the SCADA client 4 and the monitoring control device (HMIS1) 5 are omitted. Illustration of the wiring between 52. In order to improve the reliability, the monitoring control device (HMIS1) 5 and the monitoring control device (HMIS2) 7 may be configured to be redundant.

In the first embodiment, only one monitoring control device (HMIS1) 5 is provided. On the other hand, in the second embodiment, a plurality of stations are provided as monitoring and control devices for the servo terminals. Specifically, in addition to the monitoring control device (HMIS1) 5, a monitoring control device (HMIS2) 7, ..., a monitoring control device (HMISn) (not shown) is provided as a servo terminal.

In the example shown in Fig. 5, the monitoring control device network 32 includes the monitoring control device (HMIC1) 1 and the monitoring control device (HMIC2) 3, the monitoring control device 5 (HMIS1), and the monitoring control device (HMIS2) 7 connect them.

In the monitoring control device (HMIS2) 7 of the present embodiment, similarly to the monitoring control device (HMIS1) 5, the single-output function unit 52 is provided outside the SCADA servo terminal 8. The single-output function unit 52 has a function of transmitting and receiving data to and from the SCADA client 2 using a function for the SCADA client 2. Specifically, the function used by the SCADA client 2 can specify the monitoring control device (HMIS1) 5 or the monitoring control device. (HMIS2) 7 is the transmission target of the I/OTAG name. Therefore, the SCADA client 2 can transmit the I/OTAG name to the transmission target based on the transmission destination and the I/OTAG name set in advance for each control operation button (control content). That is, the SCADA client 2 is capable of transmitting the I/O TAG name to the single-output function portion of the different server for each pressed control operation button (control content).

Similarly, the function of the SCADA client 4 is used to transfer data to and from the SCADA client 4. Further, the single-output function unit 52 has a function of outputting the I/OTAG storage unit 30 of the SCADA servo unit 8. Specifically, the single-output function unit 52 includes a storage unit 80, a timer counting unit 85, and an output unit 82. Since the configuration of each unit is the same as the monitoring control device (HMIS1) 5 described in the first embodiment, the description thereof is omitted.

According to the second embodiment described above, the I/OTAG storage unit 20 in the monitoring control device (HMIS1) 5 and the I/OTAG storage unit 30 in the monitoring control device (HMIS2) 7 can be used to expand the I/OTAG storage unit 30. The number of I/OTAGs as interfaces in the factory control system. Further, the SCADA servo 6 and the SCADA servo 8 and the I/F program of the programmable logic controller 41 are not complicated, and the plurality of control contents can be associated with the plurality of monitoring control devices without interfering with each other. General implementation. That is, it is possible to increase the range of factory control even if the operability of the factory control is improved.

Further, in the second embodiment described above, the monitoring control device (HMIC1) 1 or the monitoring control device (HMIC1) 3 is equivalent to the application for the application. In the first item of the range, the "user terminal" and the monitoring and control device (HMIS1) 5 are equivalent to the "servo terminal" in the first item of the patent application, and the monitoring and control device (HMIS2) 7, ..... The monitoring control device (HMISn) is equivalent to the "second servo terminal" in the second item of the patent application scope, and the SCADA servo terminal 8 is equivalent to the "second SCADA servo" in the second item of the patent application. In the "end", the single-output function unit 52 corresponds to the "second single-function function unit" in the second item of the patent application, and the memory unit 80 corresponds to the "second memory unit" in the second item of the patent application. The timer counting unit 85 corresponds to the "second timer counting unit" in the second item of the patent application, and the output unit 82 corresponds to the "second output unit" in the second item of the patent application.

(industrial use possibility)

As described above, the plant control system according to the present invention can be used in a factory that uses SCADA for monitoring control.

1‧‧‧Monitoring Control Unit (HMIC1)

2‧‧‧SCADA client

5‧‧‧Monitoring Control Unit (HMIS1)

6‧‧‧SCADA server

11‧‧‧Screen A

12‧‧‧Clear button

13‧‧‧Execution button

14‧‧‧Control operation button A

20‧‧‧I/OTAG Storage

32‧‧‧Monitoring control device network

51‧‧‧Single output function

60‧‧‧Memory Department

65‧‧‧Timer counting section

81‧‧‧Output Department

Claims (2)

A factory control system is provided with: a customer terminal having a SCADA user terminal, the SCADA user terminal transmitting an I/OTAG name corresponding to a control content selected by an operator; and a servo terminal having a single transmission The output function unit and the SCADA servo end unit receive the I/OTAG name transmitted from the SCADA client end, and the SCADA servo end system manages the TAG of the SCADA, and corresponds to the single shot from the foregoing Outputting a signal output by the function unit, and outputting an I/OTAG associated with the I/OTAG name; and a programmable logic controller controlling the factory according to an I/OTAG outputted from the SCADA servo end; the aforementioned user terminal The server and the programmable logic controller are connected via a network device, and the single-output function unit includes a memory unit that stores the I/OTAG name transmitted from the SCADA user end unit; The timer counting unit starts measurement of a predetermined time set in advance when the SCADA user end unit performs an operation of executing the control content; and the output unit is in front of The predetermined time measurement timer started, with the memory for causing the transmission in the memory portion of the I / OTAG name corresponding to the control I / OTAG the ON signal is output to the SCADA server end Then, at the end of the measurement of the predetermined time, the OFF signal for canceling the transmission of the I/OTAG of the control I/OTAG is output to the SCADA servo terminal. The plant control system according to claim 1, comprising: a second servo terminal, wherein the second servo end is connected to the network device; and the second servo end is provided with a second SCADA servo end and a second single-output output function unit having the same function as the SCADA servo end of the servo terminal, wherein the second single-output function unit has the aforementioned single-shot with the servo terminal The function of the output function unit is the same; the SCADA client part can transmit the I/OTAG name corresponding to the control content to the single-output function unit, and send the second I/OTAG name corresponding to the second control content. The second single-output function unit includes a second memory unit that stores the second I/OTAG name transmitted from the SCADA user terminal, and a second timer counting unit. When the SCADA client end performs the operation of executing the second control content, the measurement is started for a predetermined period of time, and the second output unit is started at the start of the measurement at the predetermined time. So that the memory in the second memory of the first portion 2I / OTAG name corresponding to the second control I / ON OTAG transmitted signal, output to the servo 2SCADA first end portion and, thereafter, the measured period of time. At the end, an OFF signal for canceling the second erasure I/OTAG transmission of the second control I/OTAG is output to the second SCADA servo terminal.