JP2015225470A - Monitoring control system and monitoring control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow an operator who is to perform monitoring control to perform appropriate monitoring control even when the operator is unfamiliar with the monitoring.SOLUTION: The monitoring control system includes: a monitoring processing unit 112 that monitors a monitoring object facility, and, when the value obtained by the monitoring exceeds an allowance, issues an alarm; a storage unit 120 for storing the information of the monitoring object facility and the attribute information of the operator who performs the monitoring; and a monitoring control unit 111 for controlling a monitoring operation in the monitoring processing unit. Then, the monitoring control unit 111 changes the allowance for issuing an alarm on the basis of level information such as the learning level of the operator stored in the storage unit 120.

Description

  The present invention relates to a monitoring control system and a monitoring control method for performing monitoring control of equipment such as a plant.

  In a monitoring control system that monitors a plant or the like, a terminal that is monitored by an operator includes a display unit, and the display unit displays the state of the plant. And according to the displayed state, an operator operates each part of a plant using a terminal.

The monitoring control screen displayed by the display unit of the terminal when the operator performs monitoring needs to be an appropriate screen according to the monitoring state at that time. For example, a screen that shows the state of the entire plant is displayed during normal times, and when an abnormality occurs, a screen that shows the details of the abnormal part is displayed.
Patent Document 1 describes an example of a monitoring control device that performs monitoring control of a plant.

JP 2014-26547 A

According to Patent Document 1, a condition for displaying a monitoring control screen including information to be monitored is determined in accordance with the authority of the logged-in operator, and a monitoring control screen of equipment that can be operated with the authority of the operator is determined. The technology to display is described.
Displaying a monitoring control screen in accordance with the authority of the logged-in operator has been proposed and put into practical use.

  However, there are situations in which the display form is not necessarily appropriate only by performing display according to the authority of the operator. For example, even if the currently monitored operator has the authority to operate a specific part of a plant, whether or not the operator has sufficient skills to operate that part It was not judged by the monitoring and control device.

  A specific example will be described. For example, it is assumed that an operator operates a specific valve while viewing a screen of a plant monitoring control situation. At this time, if the operator has sufficient experience with respect to the operation at that location, it is immediately possible to know which valve should be operated in what manner from the monitoring control screen, and a quick response can be made. On the other hand, if the operator is unfamiliar with the operation of the corresponding valve, when some change occurs in the monitoring and control status of the plant, it may take some time until the valve operation is performed to deal with the change. High nature. Since the operator is unfamiliar with the operation, if the operation of the operator is delayed, in the worst case, the plant may be brought to an emergency stop. It is not preferable that the plant is brought to an emergency stop due to such unfamiliarity with the operator.

  An object of the supervisory control system and supervisory control method of the present invention is to enable an operator who performs supervisory control to perform precise supervisory control even if he / she is not familiar with the supervisory.

The monitoring control system of the present invention monitors a monitored facility, and provides a monitoring processing unit that gives a warning when a value obtained by monitoring exceeds an allowable value, information on the monitored facility, and an operator that performs monitoring And a monitoring control unit for controlling the monitoring operation in the monitoring processing unit.
The monitoring control unit changes the allowable value based on the level information of the operator stored in the storage unit.

The monitoring control method of the present invention includes a monitoring processing step, a storage processing step, and a monitoring control processing step.
In the monitoring process, the monitored equipment is monitored, and a warning is given when the value obtained by monitoring exceeds the allowable value.
In the storage processing step, information on the facility to be monitored and information on the operator performing monitoring are stored.
In the monitoring control process, the monitoring operation in the monitoring process is controlled, and the allowable value is changed based on the level information of the operator stored in the storage process.

  According to the present invention, the operation value of the operator is changed by changing the allowable value in the case of giving a warning when the value obtained by monitoring the monitored facility exceeds the allowable value based on the attribute information of the operator. It is possible to give an appropriate warning based on the skill level and experience of the person. For this reason, for example, when an unfamiliar operator performs monitoring control, it can cope with outputting an alarm early. In addition, for operators with a high level of skill, the allowable value can be set to a value with relatively little margin from the value at which the equipment will stop urgently, and there is no need to provide more margin than necessary during alarm output. Therefore, accurate monitoring according to the skill level becomes possible.

It is a block diagram which shows the example of the monitoring control system by one embodiment of this invention. It is a systematic diagram which shows the example of the path | route of the to-be-monitored object equipment by one embodiment of this invention. It is a timing diagram which shows the example of the detection timing in the flow volume difference by one embodiment of this invention. It is a figure which shows the example of the value for every flow volume difference measurement time by one embodiment of this invention. It is a flowchart which shows the example of the monitoring control operation | movement by one embodiment of this invention. It is a figure which shows the example of the flow volume difference setting screen by one embodiment of this invention. It is a figure which shows the example of the flow volume difference detection log | history screen by one embodiment of this invention. It is a figure which shows the example (Example 1) of the warning screen by one embodiment of this invention. It is a figure which shows the example (Example 2) of the warning screen by one embodiment of this invention. It is a figure which shows the example (Example 3) of the warning screen by one embodiment of this invention.

Hereinafter, an example of an embodiment of the present invention (hereinafter referred to as “this example”) will be described with reference to the accompanying drawings.
[1. Configuration of the supervisory control system]
FIG. 1 is a diagram showing the overall configuration of the monitoring control system 100 of this example.
The monitoring control system 100 in this example performs pipeline monitoring control, and includes an information server 110 and an operator terminal 130. The information server 110 and the operator terminal 130 are connected by a network 150. As the network 150, various wired or wireless networks such as a WAN (Wide Area Network) and a LAN (Local Area Network) can be applied. The network 150 is connected to a shut-off valve 141 that opens and closes the pipeline and a transmitter 142 that transmits a measured value of the flow rate of the pipeline. Although only one shut-off valve 141 and transmitter 142 are shown in FIG. 1, a plurality of shut-off valves 141 and transmitters 142 are actually prepared according to the configuration of the pipeline.

  The information server 110 includes a monitoring control unit 111, a monitoring processing unit 112, a communication unit 113, and a storage unit 120. The supervisory control unit 111 executes supervisory control processing steps for controlling the overall supervisory control operation in the system. Based on the control of the monitoring control unit 111, the monitoring processing unit 112 performs a monitoring processing step by executing a monitoring operation of each unit connected via the network 150. The communication unit 113 performs communication with the operator terminal 130, the shut-off valve 141, and the transmitter 142 via the network 150.

  The storage unit 120 includes an HDD (Hard Disk Drive), a ROM (Read Only Memory), and the like. The storage unit 120 includes a shut-off valve information table 121, a tank information table 122, an alarm information table 123, and an operator information table 124, and stores information of types assigned to the respective tables 121-124. The

The shut-off valve information table 121 stores information related to opening and closing of the shut-off valves 141 provided in the pipeline path.
The tank information table 122 stores information related to the tank level and availability of the tank.
The alarm information table 123 stores information on the difference in flow rate that generates an alarm in each system. A specific example of information stored in the alarm information table 123 will be described later.
In the operator information table 124, attribute information of an operator who operates the monitoring control device is stored in a predetermined storage processing step. As the attribute information of the operator here, for example, various information related to the authority and level of the operator such as the authority related to the monitoring work of the operator and the level of skill level of the monitoring work are stored.

  Further, the storage unit 120 stores a program for executing a pipeline monitoring operation. The monitoring control unit 111 reads the program from the storage unit 120 and executes it. As a result, the monitoring processing unit 112 executes a pipeline monitoring operation. When this pipeline monitoring operation is executed, a warning condition or the like is set based on information stored in the tables 121 to 124 of the storage unit 120.

  Then, information on the result of monitoring by the monitoring processing unit 112 is transmitted from the communication unit 113 to the operator terminal 130. In the operator terminal 130, based on the received monitoring state information, a monitoring state screen or the like is displayed on the display unit 136.

The operator terminal 130 is a terminal on which the operator confirms the monitoring state and operates the shutoff valve 141 and the like, and is configured by an information processing device such as a computer device or a tablet terminal.
The operator terminal 130 includes a control unit 131, a processing unit 132, a communication unit 133, a storage unit 134, an input unit 135, a display unit 136, and a card reader 137.

  The communication unit 133 communicates with the information server 110 and the like via the network 150. The storage unit 134 is configured with an HDD, a ROM, or the like. The input unit 135 includes input devices such as a keyboard and a mouse. The display unit 136 displays a screen indicating the monitoring state. The card reader 137 reads the identification card possessed by the operator. Based on the information read by the card reader 137, the control unit 131 determines the authority of the operator. When determining the authority of the operator, the operator terminal 130 communicates with the information server 110 and gives it to the operator based on the information stored in the operator information table 124 on the information server 110 side. Determine the authority granted. Simultaneously with the determination of this authority, the skill level of the monitoring work (driving work) of the operator is also determined.

  The storage unit 134 of the operator terminal 130 stores a program that executes a monitoring operation as the operator terminal. Then, the control unit 131 reads the program and causes the processing unit 132 to execute a monitoring operation based on the program. The monitoring operation by the processing unit 132 is executed while exchanging information with the information server 110 by the communication unit 133. Specifically, the processing unit 132 creates a monitoring screen based on information transmitted from the information server 110, and the display unit 136 displays the monitoring screen.

[2. Example of route of monitored equipment]
FIG. 2 is a diagram illustrating an example of a pipeline that is a monitored facility that is monitored by the monitoring control system 100. In this example, an A group tank 201 and a B group tank 202 are provided as storage tanks, and an A system path 210 and a B system path 220 are provided as pipelines. Then, using these A system path 210 and B system path 220, the oil or gas stored in the A group tank 201 and the B group tank 202 is supplied to the A group tank 203 and the B group. Supply to tank 204.

A plurality of shut-off valves 141 are arranged in the middle of the A-system path 210 and the B-system path 220. By selecting one of the “open” and “closed” states of the shut-off valve 141, the storage tank 201 is stored. , 202 to the supply destination tanks 203, 204 are selected. A pump 231 is arranged in the middle of the pipeline. Each shut-off valve 141 is opened or closed according to a command from the information server 110 or the operator terminal 130 of the monitoring control system 100.
Further, in the pipelines constituting the A-system path 210 and the B-system path 220, flow rate measuring devices (not shown) that measure the flow rate are disposed at least at two locations of the inlet and the outlet. The value measured by the flow meter is transmitted from the transmitter 142 (FIG. 1) to the information server 110 via the network 150.

[3. Example of data and allowable values detected by the supervisory control system]
FIG. 3 is a diagram illustrating an example in which the monitoring control system 100 monitors a pipeline.
Each flow rate measuring device arranged in the pipeline measures the flow rate at regular time intervals and transmits the measured value to the information server 110. Here, the fixed time during which the flow rate is measured is 10 seconds in this example. Then, the monitoring processing unit 112 of the information server 110 uses the flow rate value measured every 10 seconds to acquire 10-second flow rate difference data between the inlet and the outlet of each system path. Further, the monitoring processing unit 112 accumulates the data of the flow rate difference of 10 seconds, and acquires the data of the flow rate difference of 30 seconds, 120 seconds, and 360 seconds.

FIG. 3 is an example of a process for acquiring 30-second flow rate difference data. The information server 110 starts to acquire flow rate difference data at a certain timing t0, and at a timing t1, t2, t3, t4, t5,... Every 10 seconds, the flow rate difference data of 30 seconds from the accumulated value. Get. For example, at timing t3, the monitoring processing unit 112 obtains the flow rate difference value of 10 seconds obtained at timing t1, the flow rate difference value of 10 seconds obtained at timing t2, and the flow rate difference of 10 seconds obtained at timing t3. The data of the flow rate difference for 30 seconds is acquired. However, a flow rate difference of 30 seconds cannot be obtained at timings t1 and t2 of less than 30 seconds after the acquisition of flow rate difference data.
FIG. 3 shows an example of acquiring the flow rate difference data of 30 seconds, but the monitoring processing unit 112 of the information server 110 also supports the flow rate difference value of 10 seconds for the flow rate difference data of 120 seconds and 360 seconds. It can be obtained by adding the period.

FIG. 4 is a diagram illustrating an example of setting of a flow rate difference in which an emergency stop, report output, and leak alarm output are performed.
For emergency stop, when the monitoring processor 112 detects that the flow rate difference for 30 seconds is 80 liters or more, the monitoring processor 112 closes the shut-off valve 141 of the corresponding pipeline.

The permissible values for performing the leak alarm output and the report output are set to the same value, and a value when the skilled person drives and a value when the unskilled person drives are set.
An example of the values of the leak alarm output and the report output will be described. When an expert operates, the allowable value of the flow rate difference of 10 seconds is set to 10 liters. When the flow rate difference for 10 seconds exceeds 10 liters, the information server 110 outputs an alarm and a report. On the other hand, when an unskilled person operates, the allowable value of the flow rate difference for 10 seconds is set to 5 liters. When the flow rate difference for 10 seconds exceeds 5 liters, the information server 110 outputs an alarm and a report.

  Further, when the skilled person operates, the allowable value of the flow rate difference for 30 seconds is set to 25 liters. When the flow rate difference for 30 seconds exceeds 25 liters, the information server 110 outputs an alarm and a report. On the other hand, when an unskilled person drives, the allowable value of the flow rate difference of 30 seconds is set to 15 liters. When the flow rate difference for 30 seconds exceeds 15 liters, the information server 110 outputs an alarm and a report.

  Furthermore, when a skilled person operates, the allowable value of the flow rate difference of 120 seconds is set to 100 liters. When the flow rate difference for 120 seconds exceeds 100 liters, the information server 110 outputs an alarm and a report. On the other hand, when an unskilled person operates, the allowable value of the flow rate difference for 120 seconds is set to 60 liters. When the flow rate difference for 120 seconds exceeds 60 liters, the information server 110 outputs an alarm and a report.

  Similarly, when an expert operates, the allowable value of the flow rate difference for 360 seconds is set to 300 liters. When the flow rate difference for 360 seconds exceeds 300 liters, the information server 110 outputs an alarm and a report. On the other hand, when an unskilled person operates, the allowable value of the flow rate difference for 360 seconds is set to 180 liters. When the flow rate difference for 360 seconds exceeds 180 liters, the information server 110 outputs an alarm and a report.

As can be seen from these values, when the unskilled person drives in any period of 10 seconds, 30 seconds, 120 seconds, and 360 seconds, the information server 110 warns when the skilled person drives. When a flow rate difference smaller than the difference is detected, an alarm is issued and a report is output.
When the information server 110 issues an alarm, the operator terminal 130 that has received the alarm performs an operation to warn the operator of an abnormality in the flow rate difference. In addition, a report that records the state when an alarm is issued by the monitoring processing unit 112 in the information server 110 is created and stored in the storage unit 120, and the created report is output to the operator terminal 130. Is done. The report may be created by the operator terminal 130.
The set value of the flow rate difference shown in FIG. 4 is an example, and the set value can be changed by an operation by an operator using the operator terminal 130. An example of the screen when changing the setting value will be described later.

FIG. 5 is a flowchart illustrating a processing example according to the level of the operator when the monitoring control of the pipeline is performed by the monitoring control system 100 of the present example.
The information server 110 of the monitoring control system 100 acquires the operator identification information read by the card reader 137 included in the operator terminal 130. Then, the monitoring control unit 111 of the information server 110 obtains the authority and skill level of the operator from the information added to the identification information of the corresponding operator stored in the operator information table 124. Then, when the operator is authorized to monitor and operate the pipeline, the monitoring control unit 111 determines the level of the operator's driving operation. Specifically, the monitoring control unit 111 determines whether the operator is an expert who is used to driving or an unskilled person who is not used to driving (step S11).

If it is determined in step S11 that the operator is an expert, the monitoring control unit 111 sets the alarm output and the report output within the settings shown in FIG. (Step S12).
If it is determined in step S11 that the operator is an unskilled person, the monitoring control unit 111 outputs an alarm output and a report output within the setting shown in FIG. The case value is set (step S13). The flow rate difference allowable value set for the unskilled person in step S13 is smaller than the flow rate difference allowable value set for the skilled person in step S12.
In this way, the monitoring control unit 111 sets a value for performing the monitoring process, and causes the monitoring processing unit 112 to execute the monitoring control process.

  Note that the level of whether the operator is skilled or unskilled is determined, for example, based on the years involved in the supervisory control work of the operator. For example, when three years or more have passed since registration in the operator information table 124 of the information server 110, the monitoring control unit 111 determines that it is an expert, and when it is less than three years, the monitoring control unit 111 is unskilled. It is judged that it is a person. The decision threshold of 3 years is one example, and other years may be used. Alternatively, the monitoring control unit 111 in the information server 110 may determine the level of the operator from other factors.

[4. Example of flow difference setting screen and flow difference detection history screen]
Next, examples of a flow rate difference setting screen and a flow rate difference detection history screen that are displayed by the display unit 136 of the operator terminal 130 will be described.
FIG. 6 is a diagram illustrating an example of the flow rate difference setting screen 300. In this example, values of 10 seconds, 30 seconds, 120 seconds, and 360 seconds are individually set for the A system pipeline and the B system pipeline, respectively.
That is, on the flow rate difference setting screen 300, for the A-system pipeline, an alarm value setting location 301 for a flow rate difference of 10 seconds, an alarm value setting location 302 for a flow rate difference of 30 seconds, and an alarm value setting location 303 for a flow rate difference of 120 seconds. And an alarm value setting location 304 with a flow rate difference of 360 seconds.
In the flow rate difference setting screen 300, for the B-type pipeline, an alarm value setting location 305 for a flow rate difference of 10 seconds, an alarm value setting location 306 for a flow rate difference of 30 seconds, and an alarm value setting location 307 for a flow rate difference of 120 seconds. And an alarm value setting location 308 with a flow rate difference of 360 seconds.

  Each alarm value setting location 301 to 308 can be updated by an input operation by the operator's input unit 135 when an operator having the authority to input the set value is logged in. When the values of the alarm value setting locations 301 to 308 are updated, the control unit 131 of the operator terminal 130 transmits the update information to the information server 110. When this update information is transmitted to the information server 110, the monitoring control unit 111 updates the stored information in the alarm information table 123 of the storage unit 120 with the transmitted information. By updating the stored information in the alarm information table 123, the value of the flow rate difference for performing the alarm and report output in each state shown in FIG. 4 is updated.

  The alarm value set on the flow rate difference setting screen 300 shown in FIG. 6 is an example when the operator is an expert. The alarm value when the operator is an unskilled person is prepared by setting a different setting screen for the unskilled person. Alternatively, by performing the setting on the flow rate difference setting screen 300 for the expert, the monitoring control unit 111 of the information server 110 calculates a smaller value at a constant rate than each setting value, and the calculated value is not displayed. The setting value for the expert may be automatically set.

  FIG. 7 is a diagram illustrating an example of the flow rate difference detection history screen 400. The flow rate difference detection history screen 400 is one of the screens displayed on the display unit 136 of the operator terminal 130 when the operator monitors the pipeline. As shown in FIG. 7, the flow rate difference detection history screen 400 has a flow rate difference graph display area 401 and a display item information display area 402.

In the flow rate difference graph display area 401, a graph is displayed in which the horizontal axis represents time and the vertical axis represents the flow rate difference. Although only one pipeline graph is shown in FIG. 7, for example, a flow rate difference graph of the A system pipeline and a flow rate difference graph of the B system pipeline are overlapped in one flow rate difference graph display area 401. May be displayed.
In the display item information display area 402, explanation of each item of the graph displayed in the flow difference graph display area 401 is displayed.

Next, FIGS. 8 to 10 show display examples when the flow rate difference between the inlet and the outlet of the pipeline exceeds the set value and a warning operation is performed.
In the display example of FIG. 8, when the operator is an expert, the flow rate difference between the inlet and the outlet of the A-system pipeline for 10 seconds becomes 10 liters or more, which is a value for performing a leakage alarm output. It is an example of an alarm screen. In this example, a warning display 411 window is displayed on the flow rate difference detection history screen 400. The warning display 411 displays a warning message “Warning A system 10-second flow rate difference 11 liters”.

  The display example of FIG. 9 shows that when the operator is an unskilled worker, the difference in flow rate for 10 seconds between the inlet and outlet of the A system pipeline is 5 liters or more, which is a value for performing leakage alarm output. It is an example of an alarm screen. In this example, a warning display 412 window is displayed on the flow rate difference detection history screen 400. The warning display 412 displays a warning message “Warning A system 10 second flow rate difference 6 liters”.

The display example of FIG. 10 is an example of a warning screen when the transportation by the pipeline is urgently stopped. As described with reference to FIG. 4, the emergency stop is performed when the flow rate difference for 30 seconds between the inlet and the outlet of the pipeline is 80 liters or more. As shown in FIG. Then, an emergency stop warning display 413 window is displayed. The emergency stop warning display 413 is displayed with characters “A system emergency stop 30 seconds flow rate difference 80 liters”. 80 liters, which is the value of the flow rate difference at which this emergency stop is performed, is constant regardless of the skill level of the operator.
When the warning displays 411 and 412 shown in FIGS. 8 and 9 are performed, the background color of the warning displays 411 and 412 is green or blue, and the warning display 413 at the time of emergency stop shown in FIG. 10 is performed. In this case, the background color of the warning display 413 is set to a conspicuous color such as red.

  Thus, the timing at which the screen for warning the flow rate difference between the inlet and the outlet is different depending on whether the driver is an expert or a non-expert. For this reason, for example, when a skilled person performs monitoring, a flow rate difference warning display 411 as shown in FIG. 8 is displayed, so that measures for preventing the flow rate difference from becoming large can be easily determined. It is possible to deal with reducing the flow rate difference in a relatively short time. Specifically, the trouble caused by the increase in the flow rate difference can be solved by closing the shut-off valve of the problematic system and changing the transportation to another system.

On the other hand, when an unskilled person is monitoring, it is assumed that it takes a certain amount of time to deal with the warning after the warning is displayed. Here, in the case of this example, as shown in FIG. 9, the flow rate difference warning display 412 is performed in a situation where the flow rate difference is relatively small, so that the cause of the flow rate difference can be removed over time. It becomes possible.
Therefore, regardless of whether a skilled person performs a driving operation or a non-skilled person performs a driving operation, an appropriate warning is given according to the skill level of each driver, and transportation by pipeline is urgent. Appropriate monitoring can be performed to prevent the occurrence of an outage. Specifically, for example, when an unfamiliar operator performs monitoring control, it is possible to cope with an early warning output, to ensure the time required for operation, and to be unfamiliar with the operator. It is possible to prevent an emergency stop due to this. On the other hand, for highly skilled operators, the allowable value can be set to a value with relatively little margin from the value at which the equipment will stop urgently. This makes it possible to monitor accurately according to the skill level.
In addition, at the stage where each warning display is performed, the information server 110 creates a report on the state where the warning display is performed, so that it is possible to appropriately leave a history of the monitoring control state.

[5. Modified example]
The value for outputting a leakage alarm at each flow rate difference shown in FIG. 4 and the value for outputting a report were set to the same value. On the other hand, the value for outputting a leak alarm at each flow rate difference and the value for outputting a report may be different values. For example, the difference in flow rate at which a leak alarm is output is set to a different value when a skilled person performs monitoring and when a non-skilled person performs monitoring. The flow rate difference for outputting the report is set to the flow rate difference set for the skilled person in both cases of the skilled person and the unskilled person.
By doing in this way, the report which reports a monitoring state comes to be produced on fixed conditions regardless of whether a skilled person or a non-skilled person operates.

  Further, for example, when an unskilled person is monitoring, the operator terminal 130 displays a warning display 412 exceeding the set value for the unskilled person shown in FIG. When the value is exceeded, a warning display 411 shown in FIG. 8 may be performed.

In the examples shown in FIGS. 8 and 9, the contents of the warning displays 411 and 412 are the same except that the values of the flow rate differences are different. However, the contents of the warning displays 411 and 412 may be different display contents. .
For example, regarding the warning display 412 when the unskilled person performs monitoring, not only the value of the flow rate difference, but also a guidance message for a coping method when the flow rate difference increases may be displayed. .

  Further, the configuration of the monitoring control system of this example shown in FIG. 1 shows a preferred example, and the present invention is not limited to the system configuration shown in FIG. For example, in the description so far, the operator information table 124 of the information server 110 stores attributes such as the skill level of the operator, and the information stored in the operator information table 124 and the information sent from the operator terminal 130. The operator's skill level is judged by checking the above. On the other hand, the skill level of the operator may be determined by the operator terminal 130. Furthermore, when the monitoring control system 100 is a system that monitors a small-scale facility, the information server 110 and the operator terminal 130 may be configured as a single information processing apparatus.

In addition, with respect to the criteria for determining the skill level of the operator, in the above-described embodiment, when the number of years in which the monitoring work has been performed is a certain number or more, it is assumed that the operator is an expert. On the other hand, the skill level of the operator may be determined from other factors. For example, when the same operator counts the number of operation operations such as the number of times the pipeline shut-off valve 141 has been opened and closed in the past, and the number is equal to or greater than a certain number, the operator is an expert You may make it judge.
Or, instead of simply calculating the number of years in which the monitoring work has been performed, the accumulated time of the monitoring work, that is, the time from logging in to the operator terminal 130 until logging out is accumulated. When the actual monitoring time exceeds a certain time, it may be an expert.
In the above-described embodiment, an example is shown in which the allowable value for warning is changed in two stages, a proficient person and a non-experienced person. As described above, the allowable value for warning may be changed in more stages.

Further, the embodiment described so far is an example in which the monitoring control system is applied to a pipeline. In contrast, the present invention may be applied to facilities other than pipelines, such as factories and power plants, and plant monitoring control systems.
Further, the present invention is configured by a program (software) to be installed in the monitoring control system, and the program is installed in the information server 110 or the operator terminal 130 of the existing monitoring control system, so that the above-described embodiment is provided. You may make it perform the process demonstrated in the example. In this case, the program can be recorded on various recording media such as a semiconductor memory and an optical disc, and can be mounted on the information server 110 or the operator terminal 130 via the recording media.

  DESCRIPTION OF SYMBOLS 100 ... Monitoring control system, 110 ... Information server, 111 ... Monitoring control part, 112 ... Monitoring processing part, 113 ... Communication part, 120 ... Memory | storage part, 121 ... Shut-off valve information table, 122 ... Tank information table, 123 ... Alarm information Table ... 124 ... Operator information table 130 ... Operator terminal 131 ... Control unit 132 ... Processing unit 133 ... Communication unit 134 ... Storage unit 135 ... Input unit 136 ... Display unit 137 ... Card reader , 141 ... shut-off valve, 142 ... transmitter, 150 ... network, 201 ... group A tank, 202 ... group B tank, 203 ... group A tank, 204 ... group B tank, 210 ... system A path, 220 ... system B path 231 ... Pump, 300 ... Flow rate difference setting screen, 400 ... Flow rate difference detection history screen, 411, 412, 413 ... Warning display

Claims (6)

A monitoring processor that monitors the monitored equipment and warns when the value obtained by monitoring exceeds the allowable value;
A storage unit that stores information on the monitored equipment and attribute information of an operator who performs monitoring;
A monitoring control unit that controls a monitoring operation in the monitoring processing unit and changes the allowable value based on attribute information of an operator stored in the storage unit;
A monitoring control system comprising: The supervisory control system according to claim 1, wherein the attribute information of the operator stored in the storage unit is information related to a level of proficiency related to the monitoring work of the operator. When the level of proficiency related to the monitoring work of the operator stored in the storage unit is equal to or lower than a predetermined level, the allowable value is a value that has a margin from the value that stops the monitored facility to a predetermined value or more. The monitoring control system according to claim 2. The monitoring control system according to claim 3, wherein the warning performed by the monitoring processing unit is a process of displaying a warning text on a screen for performing monitoring control. The monitored facility monitored by the monitoring processing unit is a pipeline,
The information monitored by the monitoring processor is a flow rate difference between the inlet side and the outlet side of the pipeline,
The monitoring control system according to claim 4, wherein the flow rate difference is displayed in the warning text. A monitoring process that monitors the monitored equipment and warns when the value obtained by monitoring exceeds the allowable value;
A storage processing step of storing information on the monitored equipment and attribute information of an operator who performs monitoring;
A monitoring control process for controlling the monitoring operation in the monitoring process and changing the allowable value based on the attribute information of the operator stored in the storage process;
Monitoring control method including.

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