JP4141420B2 - Water treatment facility management apparatus, water treatment facility management method, and recording medium storing management program - Google Patents

Description

  The present invention relates to a management apparatus in which traceability is given by applying the concepts of hazard analysis and important control point techniques to a water treatment system, and more particularly to a management apparatus for water treatment equipment suitable for a water supply facility.

  Raw water, which is the raw material for tap water, is derived from rivers, dams, groundwater, etc. whose water quality cannot be controlled artificially. Therefore, in each process of water supply facilities consisting of water purification plants and water distribution pipes, operations corresponding to fluctuations in the quality of raw water Therefore, even in water supply facilities, so-called traceability is required to be able to trace the history and location shown in the concept of hazard analysis and critical control point method (HACCP).

  Therefore, in order to cope with such a case, the conventional technology has proposed a water quality management system in which a water quality monitor is installed in a water supply facility and centralized monitoring is performed at a central monitoring center (see, for example, Patent Document 1). ).

At this time, in relation to the hazard analysis and critical control point method, a food hygiene management method has been proposed in which the management company provides the content of the hazard analysis and critical control point method to the food hygiene factory (for example, (See Patent Document 2).
JP 2002-11460 A JP 2002-49660 A

  The above prior art has a problem in that it does not consider the traceability in a water supply facility equipped with a water purification plant, a water distribution pipe network, and the like, and cannot meet the safety demands of consumers.

  For example, the prior art disclosed in Patent Document 1 describes that water quality data is collected in real time and reflected in support of driving operations and response to abnormal / emergency situations, such as water purification plants and water distribution pipe networks. There is no mention of traceability in water supply facilities.

  Similarly, the traceability according to the prior art disclosed in Patent Document 2 is effective when a product can be managed individually or in a lot unit at a raw material supplier or a food manufacturing factory as in a food manufacturing process. It cannot be applied to processes in which raw materials are supplied as a continuous fluid from nature, such as water.

  Needless to say, water supply facilities handle literally tap water, which is processed in each process of the water supply facility, then sent to the hands of multiple customers via a distribution pipe network, etc. It is a fluid that is taken out irregularly and consumed, and unlike raw materials that can be packaged for each lot, the quality of raw water cannot be managed in lots.

  An object of the present invention is to provide a water supply management system in which traceability is given to tap water generated from raw water such as river water.

In the water treatment facility provided with a plurality of processes for generating purified water from raw water,
Means for collecting at least one of water quality, water quantity, chemical injection quantity, and chemical injection rate as process data of the water treatment facility in a plurality of processes in which the raw water is purified; and processes collected by the collecting means It means for calculating, based at least one of historical data in the facility database of the water treatment facility, operation results of at least one process data record by Ri that is calculated on the means for calculating said at least one history Means for editing the information into traceability information and storing it in the traceability database, and the data stored in the traceability database is displayed as a traceability screen.

In this case, in the management device of the water treatment facility, if any of the process data the collected exhibited outside the preset reference value, comprising means for detecting the process in which the process data is collected It said means for collecting is in the process of the raw water Yuku been purified, may be to collect process data from the upstream side of the process than the process described above detected.

The above object can also be achieved by the water treatment facility management apparatus, wherein the process of the water treatment facility includes at least one of condensation, precipitation, filtration, disinfection, and transportation .

At this time, in the water treatment facility management apparatus, the process of the water treatment facility includes a disinfecting chemical injection process, and the chemical information and chemical injection rate in the disinfecting chemical injection process and the residence time of the process are tracked. A tracking function may be provided .

In the water treatment facility management apparatus, the history data may include chemical acceptance information from the disinfectant chemical supplier .

Similarly, in the water treatment facility management apparatus , the process of the water treatment facility may include a filtration process, and the history data may include a filtration rate in the filtration process .

Further, the above object is to provide a water treatment facility management method comprising a plurality of processes for generating purified water from raw water, and at least a water quality, a water amount, a chemical injection amount, and a chemical injection rate in the plurality of processes in which the raw water is purified. Means for collecting one type as process data of the water treatment facility, calculating at least one history of the collected process data based on a facility database of the water treatment facility, and calculating the at least one type of history A management server that edits the calculation result of the history of at least one type of process data calculated in accordance with the above into traceability information , stores it in the traceability database, and displays the traceability information stored in the traceability database as a traceability screen; The server receives the process data Be assumed that receives via the network from the clean water controller and the terminal of the water treatment facility is achieved.

Further, the object is to provide at least one kind of water quality, water amount, chemical injection amount, and chemical injection rate in a plurality of processes in which the raw water is purified in a water treatment facility having a plurality of processes for generating purified water from raw water. and a function of collecting the process data of the water treatment facility, and a function of calculating, based at least one of a history of process data collected by the function of the collecting facility database of the water treatment facility, the ability to the operational A function of editing the calculation result of the history of at least one type of process data calculated by the process into traceability information and storing it in a traceability database; a function of displaying the traceability information stored in the traceability database as a traceability screen; and the process the data, the water treatment facility And a function of receiving via the network from the clean water controller and a terminal, is also achieved by a storage medium storing a program for causing a computer to execute.

  In addition, the present invention edits and displays a history tracking function for tracking an operation history performed on raw water based on process data, facility data, and chemical data of a water treatment facility, and an operated process and time. It has a function.

  Furthermore, the present invention diagnoses that the process data of the water treatment facility is within a preset reference value, detects a measurement point of the process data that is outside the reference value range, and is upstream of the measurement point. It has a history tracking function that tracks the history of operations performed on raw water for the process.

  Further, the present invention manages the drug information acceptance history from the chemical supplier and tracks the operation history of the process for injecting the chemical when the chemical contact time and the received chemical history are tracked. It has a tracking function.

  Next, the present invention provides an operation performed on raw water based on process data, facility data, and chemical data of a water treatment facility in a management server that receives a plurality of process data of the water treatment facility via a network. It is a method characterized by having a history tracking function for tracking a history.

  Furthermore, the present invention is configured such that the operation to be tracked by the history tracking function includes at least one of aggregation, precipitation, filtration, and disinfection among the processes of the water treatment facility.

  In addition, the present invention tracks the chemical information received, the chemical injection rate, and the contact time when chemicals are injected in the process of the water treatment facility, and the filtration rate when the process of the water treatment facility is a filtration process. It is characterized by tracking.

  In addition, the present invention is characterized by a storage medium storing a program for executing a history tracking function for tracking an operation history performed on raw water based on process data and facility data of a water supply facility. Is.

  According to the present invention, since it is possible to grasp what kind of operation the tap water supplied to the consumer is receiving, it is possible to quickly carry out the factor identification when an abnormality is found in the tap water. Traceability becomes possible.

  Furthermore, according to the present invention, the concept of traceability can be applied to the hazard analysis for water supply and the important control point method, so that it is possible to appropriately perform hazard analysis, process priority management, or recording.

  Hereinafter, the water treatment facility management apparatus according to the present invention will be described in detail with reference to the illustrated embodiment. Here, FIG. 1 is an embodiment of the present invention, and the water management system is as illustrated. It is comprised from the management server 1 and the terminal 2, the monitoring control server 3, the network 4, the water purification controller 5, and the water supply facility 6, and the case of the water purification plant is shown as an example as the water supply facility 6 at this time.

  Accordingly, in this water supply facility 6, the raw water 60 taken from a water source such as a river, a dam, or groundwater is converted into a water supply 69 through each process of a landing well 62, a coagulation sedimentation basin 64, a filtration basin 65, and a chlorine disinfection 67. At this time, the quality and flow rate of the raw water are measured by the sensor 61, the quality and flow rate of the precipitated water are measured by the sensor 62, the quality and flow rate of the filtered water are measured by the sensor 63, and chlorine disinfection is performed. The quality and flow rate of the purified water is measured by a sensor 68.

  First, in the landing well 62, powdered activated carbon is injected from the activated carbon injection facility 70 in order to adsorb and remove odor components in the water. Next, in the coagulating sedimentation basin 64, chemicals such as a coagulant, an acid agent, and an alkali agent are injected from the chemical injection facility 71, thereby coagulating turbid components in the raw water and forming a turbid mass called floc. Thereafter, the flocs are settled and removed.

  Next, in the filtration basin 65, chlorine is injected from the chemical injection facility 72 in order to remove turbidity, manganese, etc. that could not be removed in the coagulation sedimentation basin 63, thereby oxidizing soluble manganese and iron into insoluble substances. And captured by the filtration basin 65. Accordingly, in the coagulation sedimentation basin 64 and the filtration basin 65, the drainage treatment shown in the figure is executed when a certain period of time has elapsed, and the sediment is removed.

  After the filtration basin 65, chlorine is injected again from the chemical injection facility 73 at the entrance of the chlorine sterilization pond 67 for the purpose of sterilization, and further an alkaline agent is injected for the purpose of pH adjustment.

  The water thus obtained at the outlet of the chlorine disinfection pond 67 is called purified water. In this embodiment, the purified water is pressurized by a pump to become water supply 69, and this water supply 69 is connected to a distribution reservoir (not shown) and a water pipe ( It will be supplied to customers through water distribution facilities (not shown).

  At this time, the water purification controller 5 uses the water quality data and flow rate data measured by the sensors 61, 64, 66 and 68, and the chemical injection amount data or chemical injection rate data measured by the chemical injection facilities 70, 71, 72 and 73. In addition to collecting various process data, the control of each process of the water supply facility 6 is performed, and the water supply 69 purified from the raw water 60 is generated.

  Here, the water quality data includes turbidity, residual salt amount, pH, ultraviolet absorbance, TOC (total organic carbon), electrical conductivity, and the like. The water purification controller 5 is connected to the monitoring control server 3 via the network 4. Connected, and collects process data and control settings from each other.

  Here, the management server 1 is made up of a computer such as a personal computer or software on the computer, for example, and receives process data from the monitoring control server 3 or the water purification controller 5 via the network, and when the data is received. For example, a history of operations and water quality performed in each process until the water supply 69 is generated is tracked and edited as traceability information.

  The terminal 2 is a personal computer or a portable terminal that can be connected to the network 4 and is used to access the management server 1 and the monitoring control server 3 and receive operation settings and information provision of the water supply facility 6.

  Next, FIG. 2 is a detailed view of the management server 1 in this embodiment. As shown in FIG. 2, this management server 1 includes a CPU 10, a facility database 11, a process database 12, a traceability database 13, a medicine database 16, and a data entry. An output terminal 14, a network interface 15 (IF), and a memory 17 are provided.

  The memory 17 stores a program including a data collection function 20, an abnormality monitoring function 21, a history tracking function 22, a WEB server function 23, and a medicine management function 24. The CPU 10 executes the program, Activate various functions.

  At this time, the network interface 15 first serves to communicate information with the monitoring control server 3, the water purification controller 5, and the terminal 2 connected to the network 4, and as a result, the database 16 is sent from the network 4. Information, information generated by executing a program group stored in the memory 17, and information set from the terminal 14 are stored.

  On the other hand, the process data sent from the monitoring control server 3 or the controller 5 is stored in the process database 12. At this time, water quality test data inputted manually from the terminal 2 and the data input / output terminal 14 are also stored. And stored in the process database 12 as process data.

  At this time, the facility database 11 stores information on the civil engineering structure, piping, chemical injection equipment, instrumentation, etc. of the water supply facility 6, but it is also desirable to store the contact area with the raw water, and the residence time It is desirable to store material information for long civil structures and pipes.

  Further, the medicine database 16 stores information such as the type, components, and quantity of medicine stored in the medicine tank of the medicine injection equipment, manufacturing information of the supplier, and the date and time of receiving the medicine.

  Here, the data collection function 20 functions to collect process data of the water supply facility 6 transmitted from the monitoring control server 3 or the controller 5 through the network interface 15 and store it in the process database 12.

On the other hand, the abnormality monitoring function 21 calculates an instantaneous value, an integrated value, an average value, and a change rate of the process data of each part of the water supply facility 6, and first diagnoses the reliability of the process data. The single or multiple process data determined to be normal are diagnosed as to whether or not they are within the reference value range compared to a preset reference value. Is determined.

  As the reference value at this time, an upper limit or lower limit of data, a statistical analysis value, a correlation analysis value, or the like is used, and these are input from the terminal 2 or the data input / output terminal 14 in advance. Then, the diagnosis result such as the monitoring point where the occurrence of the harm is detected and the occurrence time is stored in the traceability database 13, and the history tracking function 22 is notified of the occurrence of the harm at the same time.

  Therefore, the history tracking function 22 is a process in which the raw water 60 led to the water supply facility 6 is purified from the information in the process database 12, the facility database 11, and the medicine database 16 into precipitated water, filtered water, purified water, water supply, and the like. , Calculate the water quality, the amount of water, the history of operations performed in the process, and edit it as history data. The obtained editing data is stored in the traceability database 13.

  At this time, as described above, the history tracking function 22 is activated in response to a notice of occurrence of harm from the abnormality monitoring function 21, but is activated in response to a request from the terminal 2 or the data input / output terminal 14, or It is also activated periodically.

  Next, the WEB server function 23 uses the data stored in the facility database 11, the process database 12, the traceability database 13, and the medicine database 16 through the terminal 2 connected to the network 4 and is permitted to be referred to. Edit and publish.

  For example, when the user receives a data request from the terminal 2, the WEB server function 23 searches the data regarding the target facility by the user ID or password and provides the information.

  At this time, the WEB server function 23 notifies the terminal connected to the network 4 of the presence / absence of the abnormality and the traceability information by e-mail or the like, so that even if the user does not access the management server 1, In addition, as shown in FIG. 9 to be described later, the information can be referred to from the management center 31 and the maintenance management company 32.

  Next, the medicine management function 24 saves in the medicine database 16 the kind, amount, component, date and time of receipt, manufacturing information of the medicine supply company, etc. stored in the medicine tank at the timing of medicine acceptance. If there is a remaining amount at times, the component change due to mixing with the receiving chemical is calculated.

  At this time, information on the medicine to be accepted may be input from the terminal 14 or may be input from the terminal 2 via the network interface 15 as part of the process data.

  Here, FIG. 3 shows an example of the configuration of the history tracking function 22. Here, the position of the water supply 69 after chlorine disinfection from the terminal 2 or the abnormality monitoring function 21 is set as a reference point, and the reference time is shown. An example when a request for previous history tracking is received is shown in the flow.

  First, in step 100, the upstream process when water supply is used as a reference point is searched as a passing process among the facility information of the water supply facility 6 stored in the facility database 11, and the facility information of these passed processes is obtained. read out.

  In this case, it is a process through which the landing well 62, the coagulation sedimentation basin 64, the filtration basin 65, and the chlorine disinfection basin 67 have passed. Therefore, the facility information includes, for example, the volume of the landing well 62, the volume of the coagulation sedimentation basin 64, Information on the volume of 65, the volume of the chlorine disinfection pond 67, chemical injection equipment and injection point, sensor installation point, and the like.

  In step 101, process data past from the reference time is collected from the process database 12 for the passed process, and drug information from the reference time is also collected from the drug database 16 for the same passed process.

  In step 102, the time at which the inlet of the passed process is reached, the time at which the outlet is reached, and the residence time are calculated from the past flow rate data and the volume of each process.

  In subsequent steps 103, 104, 105, and 106, the water quality data is searched using the time when the raw water reaches the process inlet and outlet as a key, and the operation history and residence time applied in the process are calculated.

  The output of each step at this time is, for example, activated carbon injection operation and contact time in the landing well 62 in step 103, chemical injection operation and residence time in the coagulation sedimentation basin 63 in step 104, and chlorine injection in the filtration basin 64 in step 105. The operation and the filtration speed are the chlorine injection operation and the residence time in the chlorine disinfection pond 67 in Step 106, and these pieces of information are stored in the traceability database 13.

  At this time, materials such as pipes and structures constituting the water supply facility 6 are further read out from the facility database 11, and the amount of elution is assumed to have been eluted in the water, and the elution amount is processed, and the traceability database 13 is obtained. You may make it store in.

  Next, FIG. 4 shows an example of the configuration of the medicine management function 24. Here, an example of the medicine management function when medicine acceptance information is input from the terminal 2 is shown in a flow.

  First, in step 200, the currently received medicine information from the medicine tank and the medicine supplier is received from the terminal 2. Here, the received chemical information includes the date and time of reception, chemical type, concentration, density, manufacturing date, product lot number, and the like.

  In the next step 201, the remaining amount information of the chemical tank is read from the process database 12 and the chemical database 16. At this time, for example, chemical water level measurement data in the chemical tank is read from the process database 12, the remaining amount of chemical is calculated based on the tank volume information, and the previous chemical information is read from the chemical database 16.

  In the next step 202, the current acceptance information is compared with the previous medicine information, and if the concentration, density, etc. are different, the averaging process is performed, and the current acceptance medicine information is stored in the medicine database 16.

  Next, FIG. 5 shows an example of the configuration of the abnormality monitoring function 21, and the abnormality monitoring function shown in this flow is executed at regular intervals or at the timing when the process data is updated.

  First, in step 300, time series data of a plurality of monitoring points are read from the process database 12, and instantaneous values, integrated values, average values, and change rates of the process data are calculated. In step 301, the absolute value of the process data The reliability of each data is diagnosed by determining the upper and lower limits of the rate of change and determining statistical processing.

  In the subsequent step 302, the reliability of the data is diagnosed from the correlation between the process data determined to be normal in the step 301. In the next step 303, the reference value set in advance by the terminal 2 or the data input / output terminal 14 is used. It is judged whether it is within the range, and if it is out of the standard value range, it is determined that harm has occurred. In step 304, information such as the time of occurrence of the harm and the monitoring point is stored in the traceability database 13.

  Next, the traceability screen displayed on the terminal 2 by the management server 1 will be described. First, FIG. 6 shows, as a traceability screen, water quality data and a water quality trace, together with a monitoring point and a time 400 as a reference for history tracking. This is an example of such a case.

  In the case of FIG. 6, first, as water quality data, sensor data 401 representing a reference monitoring point, daily water quality test data 402, and monthly water quality test data 403 are displayed. Next, as a water quality trace, The processes searched by the history tracking function 22, that is, the process 404 and the process exit passage time 405, the water quality 406 at the process exit, and the chemical injection operation 407 as the process operations are displayed in the order of the processes.

  Next, FIG. 7 shows an example in which a process trace is displayed as a traceability screen together with a monitoring point serving as a history tracking reference and time 400. In this case, the process searched by the history tracking function 22 That is, the passed process 408 and the passing time 405, the flow rate passing through each process, the filtration rate 410, and the chemical injection operation 411 as the process operation are displayed in the order of the processes.

  Therefore, according to this embodiment, it is possible to grasp from the traceability screen what kind of operation the tap water supplied to the consumer is undergoing, and as a result, when an abnormality is found in the tap water Traceability that enables quick identification of factors becomes possible.

  As a result, according to this embodiment, since the concept of traceability can be applied to the hazard analysis and important control point method of water supply management, it is possible to appropriately perform hazard analysis, process priority management, or recording.

  By the way, this invention can be grasped | ascertained also as a business model. Accordingly, an example in which the above embodiment is applied to business will be described with reference to FIG. 8. Here, first, the water supply facility owner 30, the management center 31, and the maintenance management company 32 are business parties, and the management center 31. The management server 1 according to one embodiment of the present invention is installed.

  Here, first, the water facility owner 30 is a business that owns a facility that manufactures and distributes drinking water, and is represented by a water utility. The water supply facility owner 30 is provided with a monitoring control server 3 for the water supply facility and a terminal 2 that receives data of the management center 31.

  At this time, a predetermined contract is concluded between the management center 31 and the water facility owner 30. This contract relates to the provision of process data and the use of the traceability service from the water facility owner 30. From the perspective of 31, it relates to the collection of process data and service provision, and the number of information provision, information content, contract period, measurement location, etc. are set by mutual agreement.

  Here, the monitoring control server 3 may be owned by the water supply facility owner 30, or may be lent or supplied from the management center 31. In addition, the contract condition between the management center 31 and the water supply facility owner 30 at this time may be only a water purification plant, or may include a water supply facility, a water distribution facility, and a water supply facility.

  Next, a contract is received between the maintenance management company 32 and the management center 31 to provide traceability provided by the management center 31. This contract is related to service provision from the management center 31 and is related to the use of information service from the maintenance management company 32. The number of information provision, information content, contract period, measurement location, payment conditions, etc. are set for each contract. As a result, the maintenance management company 32 can obtain information from the management center 31 through the terminal 2.

  At this time, information transmission between the water facility owner 30, the maintenance company 32, and the management center 31 is performed via information transmission means such as a network and electronic data media. The management server 1 provided in the management center 31 is composed of, for example, a computer, and is composed of a computer such as a personal computer and software on the computer.

  And the management server 1 will calculate the traceability of the whole basin, and will show it to a said user, if the process data from the some water supply company owner 30 is received via a network.

  Here, the water supply facility owner 30 can also operate the water supply facility on its own, but in this embodiment, the operation management operation itself of the facility is carried out by the maintenance management company 3 by a contract with the maintenance management company 32. It is supposed to be implemented.

  In this embodiment, the water facility owner company 30, the management center 31, and the maintenance company 3 are separated, but these three parties may be integrated. Alternatively, the water supply facility owner 30 and the management center 2 may be integrated, or the management center 31 and the maintenance management company 32 may be integrated.

  In FIG. 8, only one each party is shown, but there is a case where one management center 31 communicates with a plurality of water supply facility owners 30, and one management center 31 has a plurality of maintenance. Although there is a case of exchanging with the management company 3, in this embodiment, any form can be applied.

  Next, another example of the case where the above embodiment is applied to business will be described with reference to FIG. 9. In this case, the management center 31 includes the water facility owners 30A, 30B, and 30C, and the maintenance management company 32 and the network. 4 are connected.

  Therefore, all of the water facility owners 30 </ b> A, 30 </ b> B, 30 </ b> C and the maintenance management company 32 access the management server 1 installed in the management center 31 via the network 4. At this time, the management server 1 is provided with predetermined security so that only the contractor can access it.

  And each water supply facility owner 30A, 30B, 30C owns water supply facility 6A, 6B, 6C, respectively. For this reason, for example, the water facility owner 30A is provided with a monitoring control server 5A and a terminal 2A connected to the network 4, and the monitoring control server 5A transmits process data from the water facility 6A to the management server 1. It is supposed to be. Similarly, the water supply facility owners 30B and 30C are also provided with their respective monitoring control servers 5B and 5C, and transmit process data of their own water supply facilities.

  On the other hand, the terminal 2A is a personal computer or portable terminal that can be connected to the network 4, and is used to receive information from the management server 10, and this is also the same. Terminal 2B, 2C, and receives information from the management server 10.

  Therefore, the management server 1 of the management center 31 receives the process data transmitted from the water facility owners 30A, 30B, 30C, manages the traceability of tap water manufactured and transported in the water facility, and provides traceability. Is distributed to the water supply facility owner 30 and the maintenance company 32.

  At this time, the maintenance management company 32 entrusts maintenance of the water supply facilities from the water supply facility owners 30A, 30B, 30C. Then, traceability is collected using the terminal 2. In addition, although the case where there are a plurality of water supply facility-owning businesses will be described here, the number of businesses may be one.

  Here, as a specific effect by the embodiment of FIG. 8 and FIG. 9, it is possible for the water facility owner and the maintenance company to receive the information service anytime and anywhere and reduce the burden.

  In addition, according to these embodiments, since advanced management related to traceability can be entrusted to the server, there is an effect that the burden of securing staff can be reduced, and a plurality of business entities can be shared with a common function. Since it is managed, communication between operators can be promoted, and in particular, awareness of the wide-area water environment is increased.

  At this time, for the management center 31, even if a change in operation management occurs in a plurality of water facilities due to various changes such as a change in population, a change in process, and a change in water source water quality, the management server in the management center 31 It is possible to easily cope with only one change and grasp the change.

  In addition, according to these embodiments, it is possible to appropriately operate facilities distributed in a wide area, smooth and improve the efficiency of operations, and provide appropriate advice for crisis management, capital investment, etc. I can deal with it. In addition, at this time, the service user does not need to purchase and set up computer software, and further support version upgrade, and can obtain traceability information at a low cost.

  Here, for water quality management, it is necessary for each business operator and each company to secure sufficient staff. However, securing such staff is a heavy burden on the performance of the business because conditions such as the financial situation of the business and personnel composition must be met, and at this time, according to these embodiments, traceability Information collection and distribution can be realized flexibly and at low cost.

  By the way, in the above-described embodiment, the management center is installed and described as a system that transmits and receives information by connecting to a network line. However, a data collection function, a WEB server function, a history tracking function, a medicine management function, and an abnormality The computer can be used as a management system by using software comprising a program for causing the computer to realize the monitoring function, or a recording medium (for example, CD-ROM) storing this software.

  In the above embodiment, the application of a part of the water supply facility has been described, but even when applied to a water reservoir, a water distribution pipe network, an additional chlorine process, etc. The present invention can be applied in exactly the same manner as the framework of each system.

  In the above embodiment, the case where the present invention is applied to a water supply facility has been described. However, the present invention can also be applied to facility management of other drinking water plant facilities and general continuous process factories. Needless to say.

It is a block block diagram which shows one Embodiment of the management apparatus of the water treatment facility by this invention. It is a block block diagram which shows an example of the management server in one Embodiment of this invention. It is a block block diagram which shows an example of the log | history tracking function in one Embodiment of this invention. It is a block block diagram which shows an example of the chemical | medical agent management function in one Embodiment of this invention. It is a block block diagram which shows an example of the abnormality monitoring function in one Embodiment of this invention. It is explanatory drawing which shows an example of the traceability screen by one Embodiment of this invention. It is explanatory drawing which shows another example of the traceability screen concerning one Embodiment of this invention. It is a block block diagram which shows an example at the time of applying one Embodiment of this invention to a business model. It is a block block diagram which shows another example at the time of applying one Embodiment of this invention to a business model.

Explanation of symbols

1: Management server 2: Terminal 3: Monitoring control server 4: Network 5: Controller 6: Water supply facility 10: CPU
11: Facility database 12: Process database 13: Traceability database 14: Terminal 15: Interface 16: Drug database 17: Memory 20: Data collection function 21: Abnormality monitoring function 22: History tracking function 23: WEB server function 24: Drug management function 30: Water facility owner 31: Management center 32: Maintenance company

Claims (7)

In water treatment facilities equipped with multiple processes to produce purified water from raw water,
Means for collecting at least one of water quality, water amount, chemical injection amount, and chemical injection rate as process data of the water treatment facility in a plurality of processes in which the raw water is purified;
Means for calculating at least one history of process data collected by the means for collecting based on a facility database of the water treatment facility ;
Provided means for storing the traceability database by editing the operation result of the at least one of the at least one process data record by Ri is calculated on the means for calculating a history traceability information,
A water treatment facility management apparatus, wherein data stored in the traceability database is displayed as a traceability screen. In the management apparatus of the water treatment facility of Claim 1,
When any of the collected process data indicates a range outside a preset reference value , the process data includes means for detecting the process from which the process data is collected ,
It said means for collecting, said in the process of raw water Yuku been purified, the management apparatus of water treatment equipment, characterized in that collecting process data from the upstream side of the process than the process described above detected. In the management apparatus of the water treatment facility of Claim 1,
An apparatus for managing a water treatment facility, wherein the process of the water treatment facility is at least one of condensation, precipitation, filtration, disinfection, and transportation. In the management apparatus of the water treatment facility of Claim 3,
The water treatment facility process includes a disinfectant chemical injection process;
A management apparatus for a water treatment facility, wherein a function of collecting chemical information, chemical injection rate, and residence time of the process as process data is provided in the collection chemical disinfection chemical injection process. In the management apparatus of the water treatment facility of Claim 3 ,
The water treatment facility process comprises a filtration process;
The collected process data includes a filtration rate in the filtration process . In the management method of water treatment facilities equipped with multiple processes that generate purified water from raw water ,
In a plurality of processes in which the raw water is purified, at least one of water quality, water amount, chemical injection amount, and chemical injection rate is collected as process data of the water treatment facility, and at least one of the collected process data is collected A history is calculated based on the facility database of the water treatment facility, and the calculation result of the history of at least one type of process data calculated by the means for calculating the at least one type of history is edited into traceability information to create a traceability database. A management server for storing and displaying the traceability information stored in the traceability database as a traceability screen;
The management server, the management method of the water treatment facility, characterized in that the process data is received from the water purification controller and the terminal of the water treatment facility via the network. In water treatment facilities equipped with multiple processes to produce purified water from raw water,
A function of collecting at least one of water quality, water amount, chemical injection amount, and chemical injection rate as process data of the water treatment facility in a plurality of processes in which the raw water is purified ;
A function of calculating at least one type of history of process data collected by the collecting function based on a facility database of the water treatment facility;
A function of editing a history calculation result of at least one type of process data calculated by the function to be calculated into traceability information and storing it in a traceability database;
A function of displaying traceability information stored in the traceability database as a traceability screen;
A function of receiving the process data from a water purification controller of the water treatment facility and a terminal via a network;
A storage medium storing a program to be executed by a computer .

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