KR20210158285A - Maintenance Method for Water Quality Monitoring System - Google Patents

Abstract

A maintenance method of a water quality monitoring system according to the present invention is performed by a management server, and is a method for remotely judging the failure of a plurality of facilities constituting a water quality monitoring system for monitoring the water quality of discharged sewage, the method comprising: a step (a) of counting the number of alarms to guide the failure of each of a plurality of facilities constituting the water quality monitoring system and storing same in a database; a step (b) in which in a process of repairing a facility that processes an upper process among a plurality of facilities constituting the water quality monitoring system, the number of times when equipment that processes a lower process than the equipment being repaired is repaired is counted and stored in the database; a step (c) of determining whether there is a facility that processes a lower process than the facility when a failure alarm occurs for any equipment during the operation of the water quality monitoring system; and a step (d) of calculating and guiding the rate of simultaneous failure of equipment that handles sub-processes for failure of equipment where failure alarm has occurred, if there is a facility that processes a lower process than the facility where the failure alarm occurred as a result of the determination in step (c). It is possible to quickly and accurately determine failure.

Description

Maintenance Method for Water Quality Monitoring System

The present invention relates to a maintenance method of a water quality monitoring system, and more particularly, to remotely predict and analyze failures occurring in a plurality of facilities included in the water quality monitoring system to monitor and determine water quality with high reliability and precision. It relates to a maintenance method of a monitoring system.

Sewage is water that cannot be used for human life or industrial activities because it is mixed with liquid or solid pollutants, and is discharged through drainage facilities from various sources.

When such sewage is directly discharged into a river or river, serious pollution occurs in the environment, so in general, the sewage is collected in a sewage treatment facility, purified, and discharged in many cases.

However, if the components contained in the water discharged from the sewage treatment facility do not meet the environmental standards, there is also a possibility of environmental contamination. The operation of the monitoring system is essential.

Such a water quality monitoring system is basically installed at a sewage discharge plant on the premise that it operates 24 hours a day. Therefore, it is necessary to perform the maintenance of various facilities constituting it quickly and accurately.

Conventionally, when a problem occurs during the operation of the water quality monitoring system, failures due to the same cause have occurred frequently, as it is simply a matter of finding the faulty facility on site through trial and error and repairing it. There was a problem that took a long time.

Therefore, a method for solving such problems is required.

Korean Patent No. 10-1987897

The present invention is an invention devised to solve the problems of the prior art described above, and by remotely monitoring and predicting the failures of a plurality of facilities included in the water quality monitoring system to quickly and accurately determine the failures that occur, water pollution An object of the present invention is to provide a maintenance method for a water quality monitoring system that prevents accidents and enables appropriate responses.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The maintenance method of the water quality monitoring system according to an embodiment of the present invention for achieving the above object is performed by a management server, for a plurality of facilities constituting the water quality monitoring system for monitoring the water quality of discharged sewage. A method of predicting and judging the state of a facility by remotely monitoring a failure, the step (a) of counting and storing the number of alarms guiding a failure for each of a plurality of facilities constituting the water quality monitoring system and storing it in a database, the water quality monitoring (b) step of counting the number of times in the repair process of the equipment processing the upper process among the plurality of equipment constituting the system, the number of times when the repair of the equipment processing the lower process than the equipment being repaired is made together and storing it in the database; and When a failure alarm occurs for any facility during the operation of the water quality monitoring system, (c) determining whether there is a facility that processes a lower process than the facility (c) and a failure alarm as a result of the determination in step (c) If there is a facility that processes a lower-level process than the facility where the error occurred, it includes the step (d) of calculating and guiding the rate of simultaneous failure of the equipment handling the lower-level process to the failure of the equipment in which the failure alarm occurred.

At this time, the step (a) is to count the number of alarms to guide the failure of the pre-processing equipment for a process that is treated preferentially than the metering process among the entire water quality measurement process through the water quality monitoring system and store it in the database (a-1 ) step, counting the number of alarms guiding that at least any one or more of a plurality of metering pipes performing a metering process among the entire water quality measurement process through the water quality monitoring system is not detected and storing it in a database (a Step -2) and (a-3) of counting the number of alarms guiding the failure of post-process equipment that is processed later than the metering process among the entire water quality measurement process through the water quality monitoring system and storing it in the database may include the step (a-3). .

And, in step (c), when an alarm for any metering tube occurs in the process of performing the metering process, it is determined whether there is a metering tube that handles the weighing process higher than the corresponding metering tube, and (d) After step (c), if there is no metering tube that handles the higher metering process than the metering tube in which the failure alarm has occurred as a result of the determination in step (c), step (e) of guiding the possibility of failure of the pump together will be further performed. can

In addition, the maintenance method of the water quality monitoring system according to another embodiment of the present invention for achieving the above object is performed by a management server, and a plurality of facilities constituting the water quality monitoring system for monitoring the water quality of discharged sewage. As a method for judging the failure of a water quality monitoring system, a step (A) of giving a preset weight value for each concentration of a specific component included in a fluid used in the entire water quality measurement process through the water quality monitoring system and storing it in a database, the water quality monitoring system Step (B) of measuring the concentration of the fluid flowing into a selected arbitrary facility among a plurality of facilities of (B), for each of the n concentration measurement values measured by step (B) (C) calculating the multiplication values and calculating the failure degree for any selected facility among a plurality of facilities of the water quality monitoring system by summing the n product values calculated by the step (C) ( D) step.

In this case, the optional equipment selected in step (B) may be at least any one or more of a sample water metering tube for measuring a sample and a sample storage cell in which both the sample and the mixture are mixed.

In addition, the maintenance method of the water quality monitoring system according to another embodiment of the present invention for achieving the above object is performed by a management server, a plurality of facilities constituting the water quality monitoring system for monitoring the water quality of discharged sewage In the method for determining a failure of When it is determined that an abnormality has occurred in any one of a plurality of facilities constituting the water quality monitoring system during the water quality measurement process, (b) transmitting an alert to the management server, the management server (b) When receiving the alarm of step (c) and step (c) of specifying the detailed process in progress by considering the alarm reception time and the start time and required time of each detailed process in the database in real time or seconds It includes the step (d) of displaying a list of equipment that may be responsible in relation to the detailed process specified by the

The maintenance method of the water quality monitoring system of the present invention for solving the above-mentioned problems is to be able to quickly respond to failures occurring in a plurality of facilities included in the water quality monitoring system with high reliability and precision. There are advantages that can be

In addition, according to the present invention, it is possible to prevent water pollution accidents occurring in sewage treatment facilities, and there is an advantage in that it is possible to easily analyze and manage the discharge status of water pollutants according to the conditions of each season and time.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a view schematically showing a data flow in the process of operating a water quality monitoring system, a maintenance method such as an analysis method;
2 is a view showing an example of a water quality monitoring system for applying the maintenance method of the water quality monitoring system according to each embodiment of the present invention;
Figure 3 is a view sequentially showing a plurality of processes made in the water quality monitoring system;
Figure 4 is a view showing each process of the maintenance method of the water quality monitoring system according to an embodiment of the present invention;
5 is a view showing a detailed process of step (a) in the maintenance method of the water quality monitoring system according to an embodiment of the present invention;
6 is a view showing each process of the maintenance method of the water quality monitoring system according to another embodiment of the present invention; and
7 is a view showing each process of the maintenance method of the water quality monitoring system according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be specifically realized will be described with reference to the accompanying drawings. In describing the present embodiment, the same names and the same reference numerals are used for the same components, and an additional description thereof will be omitted.

The maintenance method of the water quality monitoring system according to the present invention is performed through a management server in which a program for maintenance of the water quality monitoring system stored in a storage medium is installed, and may be installed in the management server and driven by a processor of the management server.

In addition, the maintenance program of the water quality monitoring system driven by this may be output through an image output device such as a display module, and may provide visible information to the user through a graphic user interface visualized in a terminal such as a mobile phone application. .

In particular, the storage medium in which the maintenance program of the water quality monitoring system is stored may be installed in the management server using a removable disk or a communication network, and the maintenance program of the water quality monitoring system may allow the management server to be operated by various functional means. That is, in the present invention, information processing by software is specifically realized through hardware.

Hereinafter, an algorithm applied to the maintenance method of the water quality monitoring system of the present invention executed through the management server will be described.

First, FIG. 1 is a diagram schematically showing a maintenance method such as a data flow and an analysis method in the process of operating a water quality monitoring system, and FIG. 2 is a maintenance method of a water quality monitoring system according to each embodiment of the present invention. It is a diagram showing an example of a water quality monitoring system.

1 and 2, the water quality monitoring system includes a plurality of metering tubes (10a to 10d) and a reagent receiving unit ( 20), a heating tank 30 for heating the sample measured and flowed in the metering tubes 10a to 10d, and a light quantity analysis unit 40 for analyzing the total light quantity of the sample.

The sample referred to in this embodiment means water to be analyzed for water quality, and any water such as sewage, wastewater, water supply, rainwater, groundwater, lake, river, sea, etc. can be applied.

The metering tubes 10a to 10d are components for measuring the liquid for sample analysis. In this embodiment, the metering tubes 10a to 10d include a sample water metering tube 10a for measuring the sample, The dilution water metering tube 10b for measuring the dilution water for diluting the sample, the potassium persulfate metering tube 10c for metering the potassium persulfate mixed with the sample, and the sodium hydroxide mixed with the sample are measured. Includes a sodium hydroxide metering pipe (10d) for.

At this time, the reagent accommodating part 20 is provided to supply potassium persulfate or sodium hydroxide to the potassium persulfate metering tube 10c and the sodium hydroxide metering tube 10d, respectively.

In addition, the heating tank 30 heats the sample diluted with the dilution water to perform pretreatment, and the light quantity analysis unit 40 may include a UV lamp for analyzing the total light quantity of the sample.

In addition, the light quantity analysis unit 40 may be used as a sample storage cell in which potassium persulfate and sodium hydroxide are mixed together with the diluted sample.

Meanwhile, FIG. 3 is a view sequentially illustrating a plurality of processes performed in such a water quality monitoring system.

As shown in FIG. 3 , the process performed in the water quality monitoring system is sequentially sample introduction process - washing water and dilution water introduction process - sample water metering process - dilution water metering process - potassium persulfate metering process - sodium hydroxide metering process - Heating process - consists of a total light quantity analysis process.

And, in the case of the maintenance method of the water quality monitoring system according to the present invention, it is determined that a failure has occurred in the equipment responsible for each of these processes.

At this time, if a failure occurs in the upper process in time progression, since the entire process is stopped, it is impossible to determine whether a failure in the lower process occurs, so the present invention can guide so that appropriate measures can be taken in such a situation. Hereinafter, this will be described in detail.

4 is a view showing each process of the maintenance method of the water quality monitoring system according to an embodiment of the present invention.

As shown in FIG. 4, the maintenance method of the water quality monitoring system according to an embodiment of the present invention counts the number of alarms to guide failures for each of a plurality of facilities constituting the water quality monitoring system and stores it in a database ( In step a) and in the repair process of the equipment that treats the upper process among the plurality of equipment constituting the water quality monitoring system, the number of times when the repair of the equipment that treats the lower process than the equipment being repaired is made together and stored in the database (b) of storing and (c) of determining whether there is a facility that processes a lower process than the corresponding facility when a failure alarm occurs for any facility during the operation of the water quality monitoring system; (c) If, as a result of the judgment in step ), there is a facility that processes a lower process than the facility where the failure alarm occurred, step (d) of calculating and guiding the rate of simultaneous failure of the equipment that handles the lower process for the failure of the equipment where the failure alarm occurred is performed. include

Specifically, in the case of step (a), in the process of operating the water quality monitoring system, the number of alarms to guide failures for each of a plurality of facilities constituting the water quality monitoring system is separately counted and stored in the database of the management server. It is a process.

That is, in the process of operating the water quality monitoring system for a certain period, the number of failures of each facility is accumulated and counted, and this is stored and recorded in the database.

And as shown in FIG. 5, in the present embodiment, step (a) is the number of alarms to guide the failure of the pre-process facility for a process that is preferentially treated over the metering process among the entire water quality measurement process through the water quality monitoring system. Step (a-1) of counting and storing it in the database, and the number of alarms to inform that the weighing is not detected for at least any one or more of the plurality of metering pipes performing the metering process during the entire water quality measurement process through the water quality monitoring system (a-2) of counting each and storing them in the database, and counting the number of alarms to guide the failure of the post-process facilities that are processed later than the metering process among the entire water quality measurement process through the water quality monitoring system and storing them in the database ( step a-3) may be included.

The pre-process facility in step (a-1) refers to a facility that performs a process before the metering process by the metering tubes 10a to 10d is performed, and includes a sample introduction process and a washing water and dilution water introduction process. It may be a related facility including a sample tank and a washing/dilution water tank installed for

That is, in step (a-1), an alarm guiding that the sample sample is not introduced into the sample tank and an alarm guiding that the washing water and dilution water are not introduced into the sample tank and the washing/dilution water tank are counted, respectively, and the database will be stored in

In addition, in step (a-2), each alarm guiding that the metering of the liquid introduced into each of the metering pipes 10a to 10d is not detected is calculated and stored in the database. Here, the number of failures of each of the plurality of metering pipes 10a to 10d may be individually counted.

The post-process facility in step (a-3) is a facility for performing the process after the metering process by the metering pipes 10a to 10d is performed, and the heating tank 30 and the light quantity analysis unit described above (40).

That is, in step (a-3), an alarm to guide that the temperature of the heating tank 30 exceeds the set temperature and an alarm to guide that any one or more of the light quantity and voltage of the light quantity analysis unit 40 decreases Each is counted and stored in the database.

Next, in step (b), a failure occurs in a specific facility in the process of operating the water quality monitoring system, and in the process of repairing the facility, the number of cases where the repair of the facility that processes a lower process than the facility being repaired is also performed is calculated and stored in the database of the management server.

As described above, if a failure occurs in the upper process in the time progression, since the entire process is stopped, it is impossible to determine whether a failure in the lower process occurs. If a failure of the processing equipment is found and repair is made, it will be counted.

That is, the steps (a) and (b) are a process of constructing big data by statisticizing information on the number of failures and repairs of each facility in the process of operating the water quality monitoring system in the past.

And, in the case of steps (c) and (d), it is a process of performing actual failure determination using big data databased on the management server when currently operating the water quality monitoring system in real time.

In step (c), when a failure alarm occurs for any facility during the operation of the water quality monitoring system, it is determined whether there is a facility that processes a lower process than the corresponding facility.

And, in step (d), as a result of the determination of step (c), if there is a facility that processes a lower process than the facility in which the failure alarm occurred, the simultaneous failure rate of the facility that handles the lower process for the failure of the equipment in which the failure alarm occurred calculated and guided.

For example, when a failure alarm occurs in a specific metering pipe 10a to 10d, the entire process is stopped and it is impossible to determine whether the post-process equipment has failed. In this case, the management server stores the By loading information, the failure guidance for the metering pipes 10a to 10d in which the failure occurred, and the simultaneous failure rate guidance for the equipment processing the sub-process can also be performed together.

However, if, as a result of the determination in step (c), there is no facility that processes a lower process than the facility in which the failure alarm occurs, the process is the lowest step, and thus step (d) may be omitted.

In addition, in step (c), when an alarm for any of the weighing tubes 10a to 10d occurs in the process of performing the weighing process, there is a weighing tube that processes the weighing process higher than the corresponding weighing tube 10a to 10d. It can be determined in detail whether or not

And as a result of the determination in step (c), if there is no metering tube 10a to 10d that handles the higher metering process than the metering tube 10a to 10d in which the failure alarm occurred, (e) to guide the possibility of failure of the pump together ) steps may be further performed.

This is because it is impossible to determine whether the weighing pipes 10a to 10d performing the uppermost weighing process among the entire weighing process are out of order, and it is impossible to determine whether the weighing pipes 10a to 10d performing the lower weighing process are operating normally. This is because the possibility of failure of the pump operating to introduce the liquid into the tubes 10a to 10d cannot be excluded.

However, as a result of the determination in step (c), if there is a metering tube 10a to 10d that processes a higher weighing process than the metering tubes 10a to 10d in which a failure alarm has occurred, the metering tube 10a that has processed the upper weighing process ~10d) is a normal operation, so it is considered that there is no abnormality in the pump and the step (e) can be omitted.

As described above, the maintenance method of the water quality monitoring system according to an embodiment of the present invention has an advantage in that it is possible to quickly respond by determining the possibility of simultaneous failure of lower equipment according to the process sequence.

6 is a view showing each process of the maintenance method of the water quality monitoring system according to another embodiment of the present invention. It is possible to determine the failure of the equipment.

As shown in FIG. 6 , in the maintenance method of the water quality monitoring system according to another embodiment of the present invention, a preset weight value is given for each concentration of a specific component included in the fluid used in the entire water quality measurement process through the water quality monitoring system. (A) to store in a database, (B) measuring the concentration of the fluid flowing into a selected arbitrary facility among a plurality of facilities of the water quality monitoring system n times, and (B) The water quality monitoring system by summing the (C) step of calculating n product values by multiplying the corresponding weight values for each of the n concentration measurement values, and summing the n product values calculated by the step (C) (D) calculating the degree of failure for an arbitrary facility selected from among a plurality of facilities.

The step (A) is a process of arbitrarily giving a preset weight value for each concentration of a specific component included in the fluid used in the water quality measurement process and storing it in the database of the management server.

Here, the term "fluid" may be any liquid, including samples and reagents, passing through the equipment of the water quality monitoring system, and the concentration of a specific component may be a concentration of a solid contained in a sample, a concentration of a reagent, and the like.

In addition to the concentrations of solids and reagents, concentrations of other components such as nitrogen, phosphorus, organics, etc. may also affect equipment failure, so the concentrations of other components may also be used as a basis for determining the setting of a weight value.

Such a weight value can be set by statistically analyzing the correlation with the equipment failure by measuring the fluid concentration in a situation in which a predetermined equipment has failed in the process of operating the water quality monitoring system in the past.

In addition, the weight value is not determined only by the concentration of a specific component of the fluid, and it goes without saying that all factors including the fluid properties that may affect equipment failure can be used as a basis for setting the weight value.

For example, the weight value may be set as shown in Table 1 below.

As shown in the example of Table 1, the fluid concentration has a greater effect on the failure of the metering tube than the failure of the sample storage cell at low concentration, and has a greater effect on the failure of the sample storage cell than the failure of the metering tube at high concentration. it can be seen that

Also, in common, it can be seen that the higher the concentration, the higher the probability of failure.

Next, in step (B), in the process of actually operating the water quality monitoring system, the concentration of the fluid flowing into a selected arbitrary facility among a plurality of facilities of the water quality monitoring system is measured n times. And accordingly, n concentration measurement values of the corresponding facility will be generated.

Here, the optional equipment selected from among the plurality of equipment means all equipment that may fail due to the influence of fluid, etc. passing or staying. It may be at least any one or more of the mixed sample storage cells.

In addition, as described above, the sample referred to in this embodiment refers to water that is to be analyzed for water quality, and any water such as sewage, wastewater, water supply, rainwater, groundwater, lake, river, and sea can be applied.

And in step (C), for each of the measured n concentration measurement values, n product values are calculated by multiplying the corresponding weight values, and in step (D), the calculated n multiplication values are summed The degree of failure of the corresponding equipment is calculated.

For example, if it is assumed in step (B) that a total of 12 concentration measurements were performed on the metering tube to obtain concentration values of 1ppm 3 times, 2ppm 3 times, 50ppm 5 times, and 100ppm 1time, (1*3)+ (1.2*3)+(4*5)+(6*1), a total of 32.6 failure degrees can be calculated C.

Alternatively, assuming that a total of 12 concentration measurements were performed on the sample storage cell in step (B) and the same concentration values were obtained 3 times at 1ppm, 3 times at 2ppm, 5 times at 50ppm, and 1 time at 100ppm, (0.2*3 )+(0.6*3)+(5*5)+(11*1), a total of 38.4 degrees of failure can be calculated.

And in consideration of the final degree of failure calculated in this way, it is possible to prevent failure of the corresponding equipment in advance and perform maintenance.

7 is a view showing each process of a maintenance method of a water quality monitoring system according to another embodiment of the present invention. It is possible to specify the equipment where the abnormality occurred by considering each start time and required time for the process in real time or in seconds.

As shown in FIG. 7 , in the maintenance method of the water quality monitoring system according to another embodiment of the present invention, each start time and required time for each detailed process constituting the entire water quality measurement process through the water quality monitoring system are displayed in real time or When it is determined that an abnormality has occurred in any one of a plurality of facilities constituting the water quality monitoring system during the (a) step of identifying and converting to a database in seconds, in the process of performing the water quality measurement process, an alarm is sent to the management server Step (b) of sending, when the management server receives the alert of step (b), the detailed process in progress considering the alarm reception time and the start time and time required for each databaseized detailed process in real time or seconds Step (c) of specifying , and step (d) of displaying a list of facilities that may be the cause in relation to the detailed process specified by step (c).

In step (a), each start time and required time for each detailed process constituting the entire water quality measurement process through the water quality monitoring system are identified in advance and converted into a database, which means that the time required for each detailed process is always constant because it does Even if a specific detailed process is completed earlier than the identified required time, the subsequent process is performed after the required time of the previous step has passed.

Accordingly, in step (b), when it is determined that an abnormality has occurred in any one of a plurality of facilities constituting the water quality monitoring system in the course of performing the water quality measurement process, an alert is transmitted to the management server.

In this case, the alert may be transmitted in real time as soon as it is determined that an abnormality has occurred, or may be transmitted according to a preset period of seconds. As such, the transmission of the alarm is made immediately or within a short period of time, so that the control server can easily analyze which process was in progress at the time the error occurred.

Next, in step (c), the detailed process in progress is accurately specified by considering the alarm reception time in step (b) and the start time and time required for each databaseized detailed process in step (a) in real time or in seconds process is carried out.

As described above, since the transmission of the alert can be performed in real time or in a cycle of seconds, in step (c), it is possible to accurately analyze which process was in progress based on the time when the alert was received.

Next, in step (d), a list of equipment that may be the cause is displayed in relation to the detailed process specified in step (c), and accordingly, it is necessary to accurately identify the equipment related to the process. Maintenance can be performed accordingly.

As described above, preferred embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the present invention other than the above-described embodiments is a fact having ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description, but may be modified within the scope of the appended claims and their equivalents.

10a~10d: Weighing tube
20: reagent receiving unit
30: heating bath
40: light quantity analysis unit

Claims (6)

In the method of determining the failure of a plurality of facilities that is performed by a management server and constitutes a water quality monitoring system for monitoring the water quality of discharged sewage,
(a) counting the number of alarms for guiding failures for each of a plurality of facilities constituting the water quality monitoring system and storing them in a database;
In the repair process of the equipment that processes the upper process among the plurality of equipment constituting the water quality monitoring system, counting the number of times when the repair of the equipment that processes the lower process than the equipment being repaired is made together and stored in the database (b )step; and
(c) determining whether there is a facility that processes a lower process than the corresponding facility when a failure alarm occurs for any facility during the operation of the water quality monitoring system; and
As a result of the judgment in step (c), if there is a facility that processes a lower process than the equipment in which the failure alarm occurred, calculating and guiding the simultaneous failure rate of the equipment handling the lower process for the failure of the equipment in which the failure alert occurred (d) )step;
containing,
How to maintain a water quality monitoring system. According to claim 1,
Step (a) is,
(a-1) counting the number of alarms guiding the failure of a pre-process facility for a process that is preferentially treated over a metering process among the entire water quality measurement process through the water quality monitoring system and storing it in a database;
(a-2) each counting the number of alarms guiding that the metering of at least any one or more of a plurality of metering pipes performing a metering process among the entire water quality measurement process through the water quality monitoring system is not detected in the database (a-2) step; and
(a-3) counting the number of alarms guiding the failure of the post-process facility that is processed later than the metering process among the entire water quality measurement process through the water quality monitoring system and storing it in a database;
containing,
How to maintain a water quality monitoring system. 3. The method of claim 2,
Step (c) is,
In the process of performing the weighing process, if an alarm for any weighing tube occurs, it is determined whether there is a weighing tube that processes a higher weighing process than the corresponding weighing tube,
After step (d),
As a result of the determination in step (c), if there is no metering tube that handles the higher metering process than the metering tube in which the failure alarm occurred, step (e) of guiding the possibility of failure of the pump together is further performed,
How to maintain a water quality monitoring system. In the method of determining the failure of a plurality of facilities that is performed by a management server and constitutes a water quality monitoring system for monitoring the water quality of discharged sewage,
(A) step of giving a preset weight value for each concentration of a specific component included in the fluid used for the entire water quality measurement process through the water quality monitoring system and storing it in a database;
(B) measuring the concentration of the fluid flowing into a selected arbitrary facility among a plurality of facilities of the water quality monitoring system n times;
(C) step of multiplying each of the n concentration measurement values measured in step (B) by a corresponding weight value to calculate n product values; and
(D) step of calculating the degree of failure for any facility selected among a plurality of facilities of the water quality monitoring system by summing the n product values calculated by the step (C);
containing,
How to maintain a water quality monitoring system. 5. The method of claim 4,
The optional equipment selected in step (B) is at least any one or more of a sample water metering tube for measuring a sample and a sample storage cell in which both the sample and the mixture are mixed,
How to maintain a water quality monitoring system. In the method of determining the failure of a plurality of facilities that is performed by a management server and constitutes a water quality monitoring system for monitoring the water quality of discharged sewage,
(a) step of identifying each start time and required time for each detailed process constituting the entire water quality measurement process through the water quality monitoring system in real time or in seconds and making a database;
(b) transmitting an alert to the management server when it is determined that an abnormality has occurred in any one of a plurality of facilities constituting the water quality monitoring system in the course of performing the water quality measurement process;
When the management server receives the alarm in step (b), step (c) of specifying the detailed process in progress by considering the alarm reception time and each start time and required time of each databaseized detailed process in real time or seconds ; and
(d) displaying a list of facilities that may be the cause in relation to the detailed process specified by step (c);
containing,
How to maintain a water quality monitoring system.

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