JP2011192039A - System for monitoring operation state of water and sewage plant - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To support operation of an operator of a water and sewage plant. <P>SOLUTION: The system for monitoring the operation state of the water and sewage plant includes; a result data gathering means 22 for gathering result data 14a for each data type of the water and sewage plant 3 in the cycle of operation parameter data 11a; an operation state evaluation means 23 for comparing operation schedule data 13a and the result data 14a for each data type, calculating an evaluation value corresponding to a difference, and storing it in operation state data 15a; a statistical processing means 26 for reading operator data 12a, associating each identifier of the operator in charge of the operation of the water and sewage plant 3 with the operation state data 15a of a shift time zone of the operator, and storing statistically processed operation management data 16a; and an operation state display means 25 for displaying the comparison result of an operation schedule and a result on a display device on the basis of the operation state data 15a, and displaying the operation data of a predetermined operator on the display device on the basis of the operation management data 16a. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an operation monitoring system for a water and sewage plant that monitors the operation of the water and sewage plant.

  In the operation of a plant such as a water and sewage plant, an operator usually determines operation parameters such as device setting values and device operation or stop timing based on the operator's own experience and intuition. Further, instead of being determined by the operator alone, there are cases where several operators discuss and determine operating parameters, or in accordance with instructions from the management department.

  On the other hand, with the recent increase in awareness of environmental problems, energy-saving operations such as CO2 reduction and eco-operation and business management are also expected in water and sewage plants. Therefore, an operation evaluation system that allows an operator to grasp the operation status of a plant is known (see, for example, Patent Document 1). There is also known a simulator that uses various data in the plant to calculate the cost and evaluate the operation cost of the entire plant (see, for example, Patent Document 2).

JP 2008-59144 A JP 2006-260519 A

  However, in the inventions described in Patent Document 1 and Patent Document 2 described above, although the utility cost and the cost of the entire plant can be evaluated, there is a problem that the operation of the plant depends on the intuition of the operator. is there. Further, since the plant must be operated on a 24-hour basis, it is not preferable that the operator makes a difference in the operation. Therefore, there is a demand for a method for supporting an inexperienced operator so that the operator can operate with peace of mind and that any operator has a certain level of skill.

  Moreover, in said patent document 1 and patent document 2, since the present driving condition is displayed, the operator had a problem that it was difficult to grasp the difference with a schedule about the present driving condition.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an operating condition monitoring system that supports the operation of an operator of a water and sewage plant.

  In order to solve the above-mentioned problems, a first feature of the present invention relates to an operation status monitoring system for a water and sewage plant that monitors the operation of the water and sewage plant. That is, the operation status monitoring system according to the feature of the present invention is a monitoring target data type collected from a water and sewage plant, operation parameter data including a data collection cycle, and an operation corresponding to the monitoring target data type of the water and sewage plant. The setting data storage means for storing the scheduled data, the identifier of the operator in charge of the operation of the water and sewage plant, and the operator data corresponding to the shift time zone of the operator in the storage device, and the cycle of the operation parameter data, Corresponding to the difference between the planned operation data and the actual data by comparing the actual operation data with the actual data collecting means for collecting the actual data of the monitored data type of the water and sewage plant, and for each monitored data type The evaluation value to be calculated is calculated and the monitoring target data type, operation schedule data, actual data and evaluation value are associated with each other. The operation status evaluation means for storing the operation status data and the operator data are read out, and for each identifier of the operator who is in charge of the operation of the water and sewage plant, the operation status data in the shift time zone that the operator is in charge of is associated with each other. The statistical processing means for storing the statistically processed operation management data in the storage device, and the comparison result between the operation schedule and the actual results are displayed on the display device based on the operation status data, and a predetermined operator is determined based on the operation management data. Operating status display means for displaying the operational data on the display device.

  When monitoring a water supply plant that distributes water from among water and sewage plants, the types of data to be monitored are a water distribution amount, a water intake amount, and a water reservoir level. The operation schedule data is predicted water distribution data, planned water intake data, and predicted reservoir water level data. The actual data is actual water distribution data, actual water intake data, and actual water reservoir water level data.

  When monitoring a sewerage plant that drains rainwater into a river among water and sewage plants, the monitored data types are precipitation, rainwater inflow, pump discharge, and river water level. The operation schedule data is forecast precipitation data, forecast rainwater inflow data, schedule pump discharge, and forecast river water level data. The actual data is actual precipitation data, actual rainwater inflow data, actual pump discharge amount, and actual river water level data.

  Here, the operation parameter data may include a threshold for outputting an alarm. In this case, it is preferable that the driving condition evaluation unit further includes an alarm notification unit that outputs an alarm when the difference exceeds a threshold value.

  In addition, the driving condition evaluation means also reads out the previous result data, compares the result data newly acquired by the result collection means with the read result data immediately before, and calculates a numerical trend. It is preferable to accumulate the operation status data.

  ADVANTAGE OF THE INVENTION According to this invention, the driving | running state monitoring system which assists operation | use of the operator of a water and sewage plant can be provided.

FIG. 1 is a diagram for explaining a system configuration of an operating condition monitoring system and functional blocks of an operating condition monitoring apparatus according to an embodiment of the present invention. FIG. 1 is a flowchart for explaining the outline of the processing of the driving situation monitoring system according to the embodiment of the present invention. FIG. 1 is a diagram for explaining a hardware configuration of an operation state monitoring apparatus according to an embodiment of the present invention. FIG. 4 is a diagram for explaining an example of the data structure of the operation parameter data of the driving condition monitoring system according to the embodiment of the present invention. FIG. 5 is a diagram for explaining an example of a data structure of operator data in the driving situation monitoring system according to the embodiment of the present invention. FIG. 6 is a diagram for explaining an example of the data structure of operation schedule data of the driving situation monitoring system according to the embodiment of the present invention. FIG. 7 is a diagram for explaining an example of the data structure of the result data of the driving situation monitoring system according to the embodiment of the present invention. FIG. 8 is a diagram for explaining an example of the data structure of the driving situation data of the driving situation monitoring system according to the embodiment of the present invention. FIG. 9 is a diagram for explaining an example of the data structure of the operation management data of the driving situation monitoring system according to the embodiment of the present invention. FIG. 10 is an example of a screen displayed by the driving situation monitoring system according to the embodiment of the present invention, and is a screen that displays a list of scheduled values and actual values of each parameter. FIG. 11 is an example of a screen displayed by the driving situation monitoring system according to the embodiment of the present invention, and is a screen that displays a scheduled value and an actual value of a predetermined parameter in time series. FIG. 12 is an example of a screen displayed by the driving situation monitoring system according to the embodiment of the present invention, and is a screen that displays the actual value of each parameter together with past statistical values. FIG. 13 is an example of a screen displayed by the operation status monitoring system according to the embodiment of the present invention, and is a screen that displays the scheduled value and the actual value of the water distribution amount in time series. FIG. 14 is an example of a screen displayed by the driving situation monitoring system according to the embodiment of the present invention, and is a screen that displays the planned value and actual value of each parameter in a graph. FIG. 15 is an example of a screen displayed by the operation status monitoring system according to the embodiment of the present invention, and is a screen that displays a list of data cases in which the actual amount of water distribution has exceeded the plan. FIG. 16 is an example of a screen displayed by the operation status monitoring system according to the embodiment of the present invention, and is a screen for displaying a graph in the case of data in which the actual amount of water distribution is greater than planned. FIG. 17 is an example of a screen displayed by the operation status monitoring system according to the embodiment of the present invention, and displays a list of cases in which the amount of water intake has not been changed after the actual amount of water distribution has exceeded the plan. It is a screen. FIG. 18 is an example of a screen displayed by the operation status monitoring system according to the embodiment of the present invention, and a graph is displayed in a case where the water intake amount is not changed after the water distribution amount has exceeded the plan. It is a screen. FIG. 19 is an example of a screen displayed by the operation status monitoring system according to the embodiment of the present invention, and is a screen that displays a list of cases where the amount of water intake is changed after the actual amount of water distribution has exceeded the plan. is there. FIG. 20 is an example of a screen displayed by the operation status monitoring system according to the embodiment of the present invention, and is a screen that displays a graph when the amount of water intake is changed after the actual amount of water distribution has exceeded the plan. is there. FIG. 21 is a diagram for explaining an example of the data structure of the operation schedule data of the driving situation monitoring system according to the modification of the present invention. FIG. 22 is a diagram for explaining an example of the data structure of the record data of the driving situation monitoring system according to the modification of the present invention.

  Next, embodiments of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals.

(Operation status monitoring system)
With reference to FIG. 1, the driving | running condition monitoring system 10 which concerns on embodiment of this invention is demonstrated. The operation status monitoring system 10 according to the embodiment of the present invention monitors the operation status of a waterworks plant among water and sewage plants, but can also be applied to a sewerage plant as described later.

  The operation status monitoring system 10 includes an operation status monitoring device 1, a monitoring control device 2, and a water supply plant 3.

  The waterworks plant 3 is a plant for supplying drinking water and other drinking water to each household and each building. The water supply plant 3 includes a water intake, a water supply facility, a pumping station, a water reservoir, and a water pipe network. The water supply network is a pipe for supplying the water from the distribution reservoir to each home, each building, and the like. The intake station draws water from the river with an intake pump and supplies it to the water supply facility. In the water supply facility, the water pumped up from the river 4 is purified by sterilization and disinfection. The purified water in the water supply facility is supplied to and accumulated in the distribution reservoir by a pump installed at the pump station. The tap water accumulated in the distribution reservoir is supplied to each household and each building via the tap water network.

  The monitoring control device 2 is a device that monitors and controls the water supply plant 3. The monitoring control device 2 acquires and accumulates data on each facility and equipment from the water supply plant 3. Further, based on a request from the operation status monitoring device 1, predetermined plant data 41 is transmitted to the operation status monitoring device 1. The plant data 41 is data such as set values and actual values of equipment in the water supply plant 3.

  The operation status monitoring device 1 compares the current operation status of the water supply plant 3 with the prediction and evaluates it to the operator, and displays the result. Furthermore, the operating condition monitoring device 1 accumulates past information, supports statistical processing, and displays it to the operator in order to support the operation of the operator.

  The operation status monitoring device 1 and the monitoring control device 2 are connected to each other via a communication network 4. The communication network 4 is, for example, the Internet or an in-house LAN.

  In the example shown in FIG. 1, the driving situation monitoring device 1 and the monitoring control device 2 are mounted on different devices, but they may be the same device.

  Next, with reference to FIG. 2, the outline of the processing in the driving situation monitoring system 10 according to the embodiment of the present invention will be described. In FIG. 2, for example, a case where the unit of operation is one day, an operation schedule is input at the beginning of the day, and statistical processing is performed at the end of the day will be described.

  First, in step S <b> 1, setting data is input to the driving condition monitoring apparatus 1. The setting data includes operation parameter data for the operation status monitoring and control device 1 to monitor the water supply plant 3, operator data of an operator who operates the apparatus, operation schedule data of the water supply plant 3, and the like. The operation parameter data input in step S1 includes a monitoring period for the monitoring control device 2, an identifier of the monitoring target equipment, and the like.

  Next, in step S2, the driving condition monitoring apparatus 1 waits for the elapse of the monitoring cycle. When the monitoring cycle elapses, in step S3, the operation status monitoring apparatus 1 transmits an acquisition request including the identifier of the facility to be monitored to the operation control apparatus 2, and the operation data from the operation control apparatus 2 as a response. To get. In step S4, the driving situation monitoring apparatus 1 compares the performance data acquired in step S3 with the driving schedule data 13 input in step S1, and evaluates the driving situation.

  In step S5, the driving condition monitoring apparatus 1 determines whether or not the difference between the schedule and the actual result is larger than a predetermined threshold in the evaluation of the driving condition calculated in step S4. If it falls within the predetermined threshold, the process proceeds to step S7. If not within the predetermined threshold, the driving condition monitoring device 1 notifies an alarm in step S6.

  In step S7, the driving situation monitoring device 1 displays the evaluation of the driving situation obtained as a result of step S4, the driving situation, and the like on the display device. At this time, the driving condition monitoring device 1 generates a graph or a table comparing the prediction and the actual result, a graph or table comparing the past actual result and the current actual result, and displays the graph or table on the display device.

  Furthermore, in step S8, the driving condition monitoring apparatus 1 determines whether, for example, the daily operation schedule ends. If it has been completed, in step S8, the driving situation monitoring device 1 performs statistical processing based on the performance data acquired in step S3 and the evaluation of the driving situation calculated in step S4. Furthermore, the driving condition monitoring device 1 performs statistical processing by associating information such as the shift of the operator who is in charge of the operation with the operator data input in step S1. If the operation schedule does not end, the process returns to step S2 and waits until the next monitoring timing.

(Operation status monitoring device)
Next, with reference to FIG. 3, the driving | running condition monitoring apparatus 1 which concerns on embodiment of this invention is demonstrated. As shown in FIG. 3, the operation status monitoring apparatus 1 according to the embodiment of the present invention includes a central processing control device 101, a ROM (Read Only Memory) 102, a RAM (Random Access Memory) 103, and an input / output interface 109. They are connected via a bus 110. An input device 104, a display device 105, a communication control device 106, a storage device 107, and a removable disk 108 are connected to the input / output interface 109.

  The central processing control device 101 reads out and executes a boot program for starting up the operation status monitoring device 1 from the ROM 102 based on an input signal from the input device 104, and further reads out an operating system stored in the storage device 107. Further, the central processing control device 101 controls various devices based on input signals from the input device 104, the communication control device 106, etc., and reads programs and data stored in the RAM 103, the storage device 107, etc. into the RAM 103. A processing device that loads and implements a series of processing described later, such as data calculation or processing, based on a program command read from the RAM 103.

  The input device 104 includes input devices such as a keyboard and a mouse through which an operator inputs various operations. The input device 104 generates an input signal based on the operation of the operator, and inputs via the input / output interface 109 and the bus 110. It is transmitted to the central processing control apparatus 101. The display device 105 is a CRT (Cathode Ray Tube) display, a liquid crystal display, or the like, and receives an output signal to be displayed on the display device 105 from the central processing control device 101 via the bus 110 and the input / output interface 109. It is a device that displays the processing result of the control device 101 and the like. The communication control device 106 is a device such as a LAN card or a modem, and is a device that connects the operation status monitoring device 1 to a communication network such as the Internet or a LAN. Data transmitted / received to / from the communication network via the communication control device 106 is transmitted / received to / from the central processing control device 101 via the input / output interface 109 and the bus 110 as an input signal or an output signal.

  The storage device 107 is a semiconductor storage device or a magnetic disk device, and stores programs and data executed by the central processing control device 101. The removable disk 108 is an optical disk or a flexible disk, and signals read / written by the disk drive are transmitted / received to / from the central processing control apparatus 101 via the input / output interface 109 and the bus 110.

  The storage device 107 of the operation status monitoring apparatus 1 according to the embodiment of the present invention stores an operation status monitoring program, an operation parameter data storage unit 11, an operator data storage unit 12, an operation schedule data storage unit 13, and performance data. A storage unit 14, an operation status data storage unit 15, and an operation management data storage unit 16 are provided. In addition, when the driving situation monitoring program is read and executed by the central processing control device 101 of the driving situation monitoring apparatus 1, the setting data input means 21, the performance data collection means 23, the driving situation evaluation means 23, the alarm notification means 24, The driving status display means 25, the statistical processing means 26, and the operator support search means 27 are mounted on the driving status monitoring apparatus 1.

  Next, with reference to FIG. 1, each part of the driving | running condition monitoring apparatus 1 is explained in full detail.

  The operation parameter data storage unit 11 is a storage area for storing operation parameter data 11a. The operation parameter data 11a is parameter data when the operation status monitoring device 1 is operated. For example, the operation status monitoring device 1 includes a monitoring target data type collected from the water supply plant 3, a data collection cycle, and a threshold value for outputting an alarm. Furthermore, the monitoring object identifier which is the identifier of the installation of the waterworks plant 3 relevant to this monitoring object data classification is included.

  The operation parameter data 11a is data shown in FIG. 4, for example. The operation parameter data 11a includes plant device performance data, a monitoring cycle, a monitoring target identifier, a monitoring target data type, and a deviation threshold between actual results and predictions. For example, in the case of a water intake pump in the water supply plant 3, the equipment performance data of the plant is data that associates the identifier of the water intake pump with the rated capacity of the water intake pump. The monitoring cycle is a cycle in which the driving status monitoring device 1 requests the monitoring control device 2 to acquire performance data. The monitoring target identifier is an identifier of a device of the water supply plant 3 that is monitored by the operation status monitoring device 1. The operation status monitoring device 1 includes the monitoring target identifier in the acquisition request for the actual data, and acquires the plant data of the monitoring target device. The deviation threshold between the actual results and the prediction is a threshold for determining whether or not to issue an alarm in the alarm notification means 24 described later. This threshold value may be set for each monitoring target identifier or monitoring target data type.

  In the embodiment of the present invention, a case will be described in which operation parameter data 11a obtains data of each parameter of an intake / pump operation / stop signal, a water distribution amount, a water intake amount, a water intake set value, and a water reservoir level.

  As described above, by specifying the monitoring cycle and the monitoring target device with the operation parameter data 11a, the load on the monitoring control device 2 can be reduced in the collection of the plant data 41. Furthermore, since it is not necessary to hold unnecessary data in the driving condition monitoring apparatus 1, the cost can be reduced.

  The operator data storage unit 12 is a storage area for storing operator data 12a. The operator data 12 a is data of an operator who is in charge of operation of the water supply plant 3. For example, the operator data 12a associates an operator identifier with an operator shift time zone. Further, as shown in FIG. 5, the identifier of each operator is associated with the career and years of experience of the operator. When the operation is performed in units of groups, the operator data 12a may associate the identifiers of the operators constituting the group with the information of individual operators.

  The driving schedule data storage unit 13 is a storage area for storing driving schedule data 13a. The operation schedule data 13 a is operation schedule data of the water supply plant 3. For example, as shown in FIG. 6, the operation schedule data 13a includes a predicted water distribution amount that is a prediction of the water distribution amount to each household, a predicted water reservoir level that is a prediction of the water level of the distribution reservoir, and a water intake amount that is taken from the distribution reservoir. This is the planned water intake. In addition, when the set value is changed, the change timing and operation information for the device are included. In the waterworks plant, the amount of water distribution is scheduled from the predicted water distribution amount and the predicted water reservoir level before operation. The amount of water distributed by the water supply plant 3 is determined depending on the season and time. On the other hand, in the reservoir, it is required to always store more than a certain amount of water.

According to the operation schedule data 13a, “the total water distribution amount expected today is 25400 m ^{3. The} power consumption necessary for this process is scheduled to be 3400 kW. To realize this operation, From 0 o'clock to 4 o'clock, the intake pump No. 1 is operated at a constant value of 500 m ^3. The fluctuation of the reservoir water level is 5.5 meters at 6 o'clock, and after 6 o'clock, the intake pump 2 The water supply plant 3 can be operated as follows: “The operation is performed until 22:00 at a constant value of 200 m ³ ”.

  The operation schedule data 13a may be input from the input device 104 or may be input from a system that plans other operations.

  The record data storage unit 14 is a storage area for storing record data 14a. The performance data 14a is performance data acquired from the monitoring control device 2 by the driving situation monitoring device 1. As shown in FIG. 7, the actual data 14 a is data in which an intake pump identifier is associated with an intake / pump operation / stop signal, a water supply amount, a water intake amount, a water intake amount set value, a water reservoir level, and the like. These data are accumulated as performance data 14a together with the time when the data is acquired.

  The driving situation data storage unit 15 is a storage area for storing the driving situation data 15a. The driving situation data 15a is data output by the driving situation evaluation means 23 described later. As shown in FIG. 8, the operating status data 15a is associated with a scheduled value, an actual value, and an evaluation value for each parameter. The evaluation value is an evaluation of the difference between the planned value and the actual value, and is calculated by the driving condition evaluation means 23 described later.

  The operation management data storage unit 16 is a storage area for storing operation management data 16a. The operation management data 16a is data obtained by performing statistical processing by associating the operation status data 15 in the shift time zone handled by the operator with each identifier of the operator in charge of the operation of the water supply plant 3. The operation management data 16a is generated based on the operation status data 15a and the operator data 12a. The operation management data 16a has a data format capable of calculating various statistical data and responding to an operator search by the operator assistance search means 27 described later.

  The operation management data 16a includes data as shown in FIG. 9, for example. The operation management data 16a includes moving averages in the past several months, standard deviation data, data compared with the same period of the previous year, data comparing operating conditions for each operator or group, past information and average processing and trend processing at that time With data showing the relationship between

  The setting data input means 21 is means for storing the operation parameter data 11a, the operator data 12a, and the operation schedule data 13a in the operation parameter data 11, the operator data storage unit 12, and the operation schedule data storage unit 13, respectively. The operation parameter data 11a, the operator data 12a, and the operation schedule data 13a may be input from the input unit 104 by an operator or the like, or from other devices that manage these data, the communication control device 106, the communication network 4 and the like. It may be input via.

  The performance data collection means 22 collects the performance data of the monitoring target data type of the waterworks plant 3 via the monitoring control device 2 in the monitoring cycle included in the operation parameter data 11a. At this time, when the performance data collection means 22 detects that the monitoring cycle has elapsed since the previous collection, the performance data collection means 22 transmits the monitoring target data type to the monitoring control device 2 and receives the performance data 14a. The record data collection unit 22 stores the received record data 14a in the record data storage unit 14.

  The driving condition evaluation means 23 compares the operation schedule data 13 with the actual data 14a for each monitoring target data type, calculates an evaluation value corresponding to the difference between the driving planned data 13a and the actual data 14a, and monitors Driving status data 15a in which the data type, driving schedule data, performance data, and evaluation value are associated with each other is generated. Further, the driving situation evaluation means 23 accumulates the generated driving situation data 15 a in the driving situation data storage unit 15.

  Here, the operating state evaluation means 23 reads the current set value and the state of the device from the actual data 14a, and compares the planned data such as the planned set value, the planned crisis state, and the planned measured value from the operation planned data 13a. . In this comparison, the driving state evaluation means 23 determines the driving state based on the difference between the actual result and the schedule. This determination result is, for example, rank evaluation such as ◎ (excellent), ○ (normal), and △ (poor) calculated based on the difference value. The driving situation evaluation means 23 may make a determination for each individual parameter, or may further make a determination including all parameters. This determination result is stored in the driving situation data 15a.

  The driving condition evaluation means 23 further reads out the previous record data 14a, compares the record data newly acquired by the record collection means 22 with the read record data 14a immediately before, and shows the tendency of numerical values. Calculate and accumulate in the driving situation data 15a. For example, the driving condition evaluation means 23 may compare with the data acquired at 10:00 of the previous time when the actual data is newly acquired at 11:00. Furthermore, the driving condition evaluation means may obtain data for several hours before 8 o'clock to 10 o'clock, and calculate an average, a change amount (trend), and the like. These data are stored as driving status data 15a.

  The warning notification means 24 outputs a warning when the difference in the driving condition evaluation means 23 exceeds the threshold included in the operation parameter data 11a. This threshold value may be, for example, in the form of “alert an alarm when the numerical value deviates by 20%” or in the form of “alert an alarm when the evaluation value becomes Δ”. Further, the alarm notification means 24 may notify whether or not to issue an alarm based only on newly acquired result data, and also considers the average and trend of the previous time zone, May be issued.

  When notifying the alarm, the alarm notifying unit 24 notifies the operator by displaying a pop-up on the display device 105 or outputting a sound.

  The statistical processing means 26 reads out the operator data 12a and performs statistical processing by associating the operation status data 15a of the shift time zone handled by the operator with the identifier of the operator in charge of the operation of the waterworks plant 3. Data 16a is generated. The statistical processing means 26 stores the generated operation management data 16 a in the operation management data 16.

  For example, the statistical processing means 26 reads the past driving situation from the driving situation data 15 a for the operation parameter stored in the operation parameter data 11. Further, the statistical processing means 26 calculates, for each parameter, a moving average from the past several months to the present, a standard deviation, a comparison with the same period of the previous year, and the like. Further, the statistical processing means 26 reads the information of the operator and the group from the operator data 12, compares each operator and the group with the past driving situation, and combines the average and tendency with the past driving situation data 15a. Etc. are calculated. In this way, the statistical processing means 26 generates data that is a target element of statistics and accumulates it in the operation management data 16a.

  The driving status display means 25 displays the comparison result between the driving schedule and the actual results on the display device 105 based on the driving status data 15a. Further, the operation status display means 25 displays operation data of a predetermined operator on the display device 105 based on the operation management data 15a.

  The driving status display means 25 displays, for example, the screens shown in FIGS. The screen shown in FIG. 10 shows the setting state of the target value. In the screen shown in FIG. 10, for each monitoring item, a list of optimum setting values that are scheduled values, current locations that are actual values, and the like are displayed. Furthermore, in the screen shown in FIG. 10, the evaluation calculated by the driving situation evaluation means 23 is associated. In addition, an allowable range that is a threshold is associated with each monitoring item. With the screen shown in FIG. 10, the operator can easily specify items with low evaluation and items with high evaluation.

  The screen shown in FIG. 11 displays the time-series data flow for a predetermined monitoring item. In the example illustrated in FIG. 11, the optimum setting value, the actual value, and the evaluation regarding operation are associated with each other for the monitoring item “water supply amount”. With the screen shown in FIG. 11, the operator can grasp time-series evaluation, and can grasp the timing at which the evaluation is deteriorated. In addition, the operator can grasp the current state by grasping the past operation state for each hour and the operation schedule in the future.

  The screen shown in FIG. 12 displays the current situation and past statistical data together. With the screen shown in FIG. 12, the operator can grasp the current state, the short-term state, the long-term operation state, and the like regarding the total driving state. Thereby, the operator can grasp | ascertain the short-term and long-term driving | running conditions.

  The operator support search means 27 is a means for searching the past operation management data 16 when the operator wants to refer to the past operation. For example, when the current numerical value or the numerical value of the previous time is input, the operator support search means 27 searches the operation management data 16a for the same situation. The operator support search means 27 displays information such as the set value of each facility in the same situation and the water level of the water intake value on the display device 105. Further, the operator assistance search means 27 may further search using the operator identifier as a key. For example, when a new operator inputs the current numerical value and also inputs the identifier of an experienced operator, the operator assistance search means 27 searches for data in the same situation that the experienced operator has operated in the past. Thereby, the new operator can operate the waterworks plant 3 with reference to the operation of the experienced operator.

(Operation example of waterworks plant)
Next, with reference to FIG. 13 thru | or FIG. 20, the case where an operation condition is monitored about the water intake amount at the time of treating the water purification plant of the waterworks plant 3 is demonstrated. Here, in particular, the operation of the water supply plant 3 conscious of energy saving will be described.

  When operating the water purification plant of the waterworks plant 3, the water intake pump is operated / stopped so that the water intake volume is as constant as possible so that the water distribution to the consumer does not stagnate with respect to the water supply volume that fluctuates depending on the usage conditions of the customer. It is desirable to do. At this time, it is expected that the reservoir buffer will be used effectively.

  On the other hand, in consideration of energy saving, it is preferable to turn the intake pump as much as possible during the night when the amount of electric power is cheap, and to set the reservoir water level as the upper limit before the morning peak. In addition, during the day, it is expected that the water level of the reservoir will not be taken up to the lower limit. It is preferable to operate so that the reservoir reaches the lower limit at around 22:00, which is the target of nighttime electric energy.

  First, as the operation parameter data 11a, the rated power of the intake pumps Nos. 1 to 4, the discount rate of the amount of electricity for the day and night, the deviation threshold between the actual result and the forecast, the monitoring cycle for monitoring every other hour, and the threshold for issuing the alarm And stored in the operation parameter data storage unit 11. Further, information on operators A and B as operating operators is stored in the operator data storage unit 12 as operator data 12a. Further, the predicted reservoir water level and the estimated intake volume set value calculated so that the reservoir water level becomes the upper limit in the morning and becomes the lower limit around 22:00 from the predicted water distribution amount and the predicted water distribution value of the day are the operation planned data 13a. Is stored in the operation schedule data storage unit 13.

  The actual data collecting means 22 is an operation / stop state of the intake pumps Nos. 1 to 4 to be monitored from the monitoring and control device 2, actual values of the distribution amount / intake amount / reservoir water level, intake water for operating the intake pump. Plant data 41 such as quantity set values is collected. The performance data collection means 22 stores the collected plant data 41 in the performance data storage unit 14 as performance data 14a.

  The operation status evaluation means 23 reads the predicted water distribution predicted value, the predicted reservoir water level, and the planned water intake set value from the operation planned data 13a, and calculates a deviation from the actual data 14a with respect to each predicted / scheduled value. When the deviation deviates from the threshold value included in the operation parameter data 11, the operation status evaluation unit 23 notifies the alarm notification unit 24 to that effect. The alarm notification unit 24 displays a guidance on the display device 105 or the like.

  Further, the operation status evaluation means 23 determines the number and number of intake pumps that need to be operated from the planned intake amount and the actual intake amount, and calculates the planned electric energy and the actual electric energy. Next, the operation state evaluation means 23 calculates the water distribution amount per 1 kW on the day, which is an index value of the operation state, from the actual power amount and the actual water distribution amount. Various types of information calculated by the driving situation evaluation means 23 are stored in the driving situation data storage unit 15 as driving situation data 15a.

  The statistical processing means 26 associates the operator data 12a with the operation status data 15a, and collects and analyzes each operator's operation method, past optimum operation examples, and the like. The operation management data 16a generated as a result is stored in the operation management data storage unit 16.

  The operator refers to the guidance of deviation deviation by the alarm notification means 24, the screen displayed by the driving status display means 25, and the like. The operator determines the change or continuation of the water intake set value by using a list or graph of the water distribution amount or water intake status on the day, and performs the optimum operation. Moreover, the operator assistance search means 27 can search the operation management data 16a about the same tendency of the water distribution amount, and can refer to the operation method.

  Here, with reference to FIG. 13 and FIG. 14, the screen which the driving | running condition display means 25 displays is demonstrated. In FIG. 13, the forecast and actual results of the water distribution at 13:00, the set and actual values of the intake water, the planned and actual water reservoir levels, and the planned and actual power consumption of the intake pump are displayed in time series. ing. FIG. 14 is a graph display of various data displayed in FIG. In FIG. 14, schedules and results are displayed in time series for the reservoir water level, water intake, and electric energy, respectively.

  Here, a case where the water distribution amount prediction greatly deviates will be described. As shown in FIG. 15 and FIG. 16, when the water distribution amount after 9 o'clock is larger than expected at D101, the water level in the reservoir will deviate more than expected at 13:00 in D102. When the lower limit of the reservoir water level is 1.5 m, as shown in FIGS. 17 and 18, if the operation is continued without changing the water intake setting at D103, the time from 19:00 to 24:00 at D104 Reservoir water level in the belt falls below the lower limit.

In this case, the water level is not reached until the reservoir is completely depleted, and the water distribution amount per kW of the energy saving index value is 17.26 m ³ / kW, which is a significantly higher value than planned. Although this looks like a good driving | operation, it will become a dangerous operation result as the whole waterworks plant 3 because it fell below the water level lower limit.

Then, the driving | running condition monitoring apparatus 1 which concerns on embodiment of this invention detects that the reservoir water level has shifted | deviated significantly from the plan at the time of 11:00. Further, the operation status monitoring device 1 can prompt the operator to change and operate the intake water set value after 12:00 by displaying a guidance to that effect. As a result, as shown in FIGS. 19 and 20, by increasing the water intake amount in D105, the reservoir water level can be operated without falling below the lower limit value. Moreover, since it can be operated at 65 m ³ / kW in D106, finally, the water distribution amount per 1 kW of the energy saving index value can be recorded as 16.39 m ³ / kW, which is almost the same as the plan. As described above, the operating state monitoring apparatus 1 according to the embodiment of the present invention allows the operator to select a stable and good operation method.

  As described above, the operation status monitoring device 1 according to the embodiment of the present invention monitors whether or not the operation status of the plant is given in advance and does not deviate from the operation conditions, and notifies the water supply as necessary. The plant 3 can be optimally operated.

  The operation status monitoring system 10 according to the embodiment of the present invention inputs the operation parameter data 11a and the operation schedule data 13a and collects the performance data 14a, so that the operation status evaluation unit 23 performs the operation schedule. And the difference between the results and the results can be compared. Therefore, the operation can be monitored to save energy. In addition, the predicted water distribution amount and the predicted reservoir water level can be input as operation schedule data from the water distribution demand prediction system of other systems. Thereby, the input load of the driving plan data in the driving condition monitoring system 10 can be reduced. The operator data 12a can further reduce the input load of other information such as the operation parameter data 11a by cooperating with the work management system and the equipment management system. Also about the collection of the performance data 14a, the monitoring target of the driving condition monitoring system 10 is specified by the operation parameter data 11a. Thereby, it is possible to collect only necessary information without imposing a load more than necessary on the monitoring control device 2 that controls the water supply plant 3.

  Moreover, in the driving | running condition evaluation means 23, this difference is computable by comparing prediction with a track record. Furthermore, the driving | running condition evaluation means 23 may evaluate a driving | running condition by a moving average, a standard deviation, a pattern matching, etc. according to a plant, equipment, a signal, etc. by acquiring a predicted value and a track record value. Further, the driving situation evaluation means 23 may evaluate the driving situation for each operator in consideration of the operator data 12a. As described above, the operation status evaluation unit 23 can evaluate the operation status of the water supply plant 3 by various arithmetic processes using the data input to the operation status monitoring device 1.

Furthermore, the driving situation data 15a calculated by the driving situation evaluation means 23 is stored as a database. In the driving status data 15a,
Furthermore, the operation management data 16a obtained by statistically processing the operation status data 15a can be generated, and the current operation status can be searched from past results. Further, by generating the operation management data 16a together with the operator information, the operator support search means 27 can collect the operation status, maturity, operation method difference, etc. for each operator.

In addition, the operating status display means 26 can notify the operator of the operating status and make it visible. The driving status display means 26 is visualized by notifying guidance for the current operating status or displaying the driving status as a list or graph. As a result, a display method suitable for the target plant and equipment can be provided, so that it is possible to assist in improving the operability and visibility of the operator.
As described above, the operation status monitoring system 10 according to the embodiment of the present invention can monitor whether the water treatment plant of the water supply plant 3 is actually operated according to the predetermined operation parameters, for example, as the plant operation of the water purification plant. it can. Thereby, it is possible to reliably support optimum operation. By visualizing the optimum operation parameter and the difference, the operation status monitoring system 10 according to the embodiment of the present invention can improve the operator's awareness of energy-saving operation.

  Furthermore, by feeding back the driving situation data 15a to a knowledge system or a simulation system, it can be used as know-how such as operator education and technical succession. In addition, by making the operator search the past operation status data 15a by the operator assistance search means 27, even an inexperienced operator can reliably operate the plant optimally while watching the status.

  The driving situation monitoring system 10 according to the embodiment of the present invention monitors whether or not it is actually operated in accordance with predetermined driving parameters. Therefore, the optimum operation can be surely performed by confirming in real time whether the actual operation is being performed as it is with respect to the optimum operation parameter utilizing the operation evaluation system or the simulation technology.

  In addition, by visualizing the difference from the operation schedule, it is possible to improve the operator's awareness of energy-saving operation.

  Furthermore, in the recent shortage of experienced operators, even inexperienced operators can reliably operate the plant optimally while observing the situation. Also, by feeding back the difference status with the actual results to the above-mentioned driving evaluation system and simulation, the situation of the difference is analyzed to determine the operator's judgment error, the simulation accuracy is insufficient, etc. Accuracy can be improved. In addition, in response to an operator's judgment error, it is possible to report whether the operation parameter change timing is good or bad or improvements.

(Modification)
In embodiment of this invention, although the water purification equipment of the waterworks system was demonstrated, it is also applicable to another system. For example, a case will be described in which the operating condition monitoring system 10 according to the embodiment of the present invention is applied to a sewer system for rainwater that stores rainwater or discharges it into a river.

  In the sewer system for rainwater, the operator determines whether to operate or stop the rainwater pump based on the rainfall situation and prediction. In addition, the operator determines whether or not to discharge the stored rainwater to the river in accordance with the amount and concentration of rainwater stored in the rainwater storage facility and the water level of the river.

  In the operation monitoring control system 10b according to the modification, the “monitoring target identifier” of the operation schedule parameter data 11a described with reference to FIG. 4 and the like is, for example, each identifier of the rainwater pumps Nos. 1 to 3. “Monitored data type” includes precipitation, rainwater inflow, pump discharge, and river water level. Further, as shown in FIG. 20, the operation schedule data 13b according to the modification is predicted precipitation data, scheduled rainwater inflow data, scheduled pump discharge amount, and predicted river water level data. The actual data acquired by the operation control device 1 from the sewer system is actual rainfall data, actual rainwater inflow data, actual pump discharge, and actual river water level data.

  Also in the operation control system 10b according to such a modification, as in the embodiment of the present invention, the difference between the actual result and the prediction can be displayed, or a warning can be output when the difference between the numerical values is large. Furthermore, numerical values can be accumulated and displayed as statistical data, or an operator can search past data.

  Moreover, although the case where it applied to the sewer system for rainwater was demonstrated in the modification, you may apply the driving condition monitoring system 10 which concerns on embodiment of this invention to the sewer system for sewage. In this case, the operation status monitoring system 10 can monitor whether or not the water quality is controlled according to the injection rate and the injection amount that are scheduled in advance according to the conditions such as season and sunshine.

  In this way, if the plant / equipment can collect plant data from the monitoring and control device and the operation target value is determined in advance, the operation parameter data and the operation schedule data are input, and the actual data is obtained from the plant. By obtaining, it can be applied to any plant.

  Furthermore, further operational support can be expected by linking the operation status monitoring system 10 according to the embodiment of the present invention with an equipment maintenance system, a simulation system, or the like.

(Other embodiments)
As described above, the embodiments and modifications of the present invention have been described. However, it should not be understood that the descriptions and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples, and operational techniques will be apparent to those skilled in the art.

  It goes without saying that the present invention includes various embodiments not described herein. Therefore, the technical scope of the present invention is defined only by the invention specifying matters according to the scope of claims reasonable from the above description.

DESCRIPTION OF SYMBOLS 1 Operation condition monitoring apparatus 2 Monitoring control apparatus 3 Water supply plant 4 Communication network 11 Operation parameter data storage part 12 Operator data storage part 13 Operation plan data storage part 14 Performance data storage part 15 Operation condition data storage part 16 Operation management data storage part 21 Setting data input means 22 Performance data collection means 23 Operating status evaluation means 24 Alarm notification means 25 Operating status display means 26 Statistical processing means 27 Operator support search means 41 Plant data 101 Central processing control device 102 ROM
103 RAM
104 Input Device 105 Display Device 106 Communication Control Device 107 Storage Device 108 Removable Disk 109 Input / Output Interface 110 Bus

Claims (5)

In the operation monitoring system of the water and sewage plant that monitors the operation of the water and sewage plant,
Monitoring target data type collected from the water and sewage plant, operation parameter data including a data collection cycle, operation schedule data corresponding to the monitoring target data type of the water and sewage plant, and operation of the water and sewage plant. Setting data storage means for storing in the storage device the operator data in which the identifier of the operator in charge is associated with the shift time zone of the operator;
Actual data collection means for collecting actual data of the monitored data type of the water and sewage plant in the cycle of the operation parameter data;
For each of the monitoring target data types, the operation schedule data and the actual data are compared to calculate an evaluation value corresponding to the difference between the planned operation data and the actual data, and the monitoring target data type, the operation Driving status evaluation means for associating the schedule data, the actual data, and the evaluation value and storing them in the driving status data;
The storage device stores operation management data obtained by performing statistical processing by reading the operator data and associating the operation status data in the shift time zone handled by the operator with each identifier of the operator in charge of operation of the water and sewage plant Statistical processing means for storing
Based on the operation status data, the operation status display means displays the comparison result between the operation schedule and the actual result on the display device, and displays the operation data of a predetermined operator on the display device based on the operation management data. A system for monitoring the operating status of a water and sewage plant. Among the water and sewage plants, when monitoring a water supply plant that distributes water, the monitoring target data type is a water distribution amount, a water intake amount and a water reservoir level,
The operation schedule data is predicted water distribution data, planned water intake data, and predicted reservoir water level data,
The said performance data are performance water distribution data, performance water intake data, and performance water reservoir water level data. The operating condition monitoring system of the water and sewage plant of Claim 1 characterized by the above-mentioned. Among the water and sewage plants, when monitoring a sewage plant that drains rainwater into a river, the monitoring target data types are precipitation, rainwater inflow, pump discharge, and river water level,
The operation schedule data is forecast precipitation data, schedule rainwater inflow data, schedule pump discharge and forecast river water level data,
The operation data monitoring system for a water and sewage plant according to claim 1, wherein the actual data is actual precipitation data, actual rainwater inflow data, actual pump discharge, and actual river water level data. The operational parameter data includes a threshold for outputting an alarm,
4. The water supply and sewage plant according to claim 1, further comprising an alarm notification unit that outputs an alarm when the difference exceeds the threshold value. 5. Operating status monitoring system. The driving condition evaluation means further reads out the previous performance data, compares the performance data newly acquired by the performance collection means with the read out previous performance data, and calculates a numerical tendency The operation status monitoring system for a water and sewage plant according to any one of claims 1 to 4, wherein the operation status data is stored in the operation status data.

Images