JP7106438B2 - Water quality measurement system and maintenance method determination method - Google Patents

Description

The present invention relates to a water quality measurement system and a maintenance method determination method.

In the process of treating water, sewage and wastewater, water quality is measured using a water quality measuring instrument. Substances contained in the water to be treated adhere to this water quality measuring instrument during use. Therefore, in order to perform accurate measurement, it is necessary to wash the water quality measuring instrument to remove the adhering substances. Therefore, various cleaning techniques have been considered (see Patent Document 1, for example).

Japanese Unexamined Patent Application Publication No. 2009-202098

In general, cleaning, calibration, and replacement of water quality measuring instruments are carried out after judging the timing and details based on the operator's experience. In order to increase the accuracy of the measurement values of the water quality measuring instrument, the frequency of judgment by the operator and the frequency of maintenance are increased. On the other hand, if the maintenance frequency of the water quality measuring instrument is reduced in order to reduce operator man-hours and the cost of consumables, the accuracy of the measurement value of the water quality measuring instrument will decrease, and the treated water quality may deteriorate. There is As described above, maintenance cannot be performed by a suitable method and timing, and there is a problem that the maintenance cost is increased and the accuracy of the measured value is lowered.

SUMMARY OF THE INVENTION An object of the present invention is to provide a water quality measurement system and a maintenance method determination method that allow maintenance to be performed by a method and timing suitable for usage conditions.

The present invention comprises at least two water quality measuring units for measuring the water quality in storage units respectively provided upstream and downstream of a processing storage unit for performing a predetermined treatment on water to be treated by a water treatment apparatus. ,
a flow rate measuring unit for measuring a flow rate flowing into a reservoir provided upstream or downstream of the processing reservoir;
a calibration information acquisition unit for acquiring calibration information, which is information when the water quality measurement unit is calibrated, from the water quality measurement unit to be maintained;
Based on the measurement result in the water quality measurement unit, the flow rate measured by the flow rate measurement unit, the calibration information acquired by the calibration information acquisition unit, and the operation status of the water treatment device, the calibration information acquisition unit A water quality measurement system having a control unit that determines a maintenance method for a water quality measurement unit that has acquired calibration information and outputs information indicating the determined maintenance method.

The calibration information acquisition unit acquires the calibration information from the water quality measurement unit provided downstream,
The control unit receives the measurement result from the water quality measurement unit provided upstream, the flow rate measured by the flow rate measurement unit, and the calibration information obtained from the water quality measurement unit provided downstream by the calibration information acquisition unit. , and the operating conditions of the water treatment apparatus, the maintenance method is preferably determined.

The calibration information acquisition unit acquires the calibration information from the water quality measurement unit provided upstream,
The control unit receives the measurement result from the water quality measurement unit provided downstream, the flow rate measured by the flow rate measurement unit, and the calibration information obtained from the water quality measurement unit provided upstream by the calibration information acquisition unit. , and the operating conditions of the water treatment apparatus, the maintenance method is preferably determined.

The control unit calculates the load amount by multiplying the measurement result in the water quality measurement unit and the flow rate measured by the flow measurement unit, and the calculated load amount and the calibration information acquired by the calibration information acquisition unit. and the operating status of the water treatment apparatus.

Preferably, the control unit displays information indicating the determined maintenance method.

further comprising a cleaning unit that cleans the water quality measuring unit;
It is preferable that the control unit determines a timing at which the cleaning unit performs cleaning as the maintenance method.

a database that associates and stores the load amount calculated by multiplying the measurement result and the flow rate, the calibration information, the operation status, and the maintenance method;
The control unit multiplies the measurement result in the water quality measurement unit and the flow rate measured by the flow measurement unit, the load amount calculated by multiplying, the calibration information acquired by the calibration information acquisition unit, and the operation of the water treatment device It is preferable to determine the maintenance method by reading the maintenance method from the database using the status as a search key.

The control unit associates the determined maintenance method, the load amount, the calibration information, and the operating status used for determining the maintenance method with the maintenance method that is appropriate, or Preferably, the inappropriate correspondence is stored in the database, and the more appropriate correspondence is selected based on the correspondence to determine the maintenance method.

Further, the present invention provides a process in which a first water quality measuring unit measures the water quality in a reservoir provided upstream of a treatment reservoir for performing a predetermined treatment on water to be treated by a water treatment apparatus;
a process in which a second water quality measuring unit measures the water quality in a reservoir provided downstream of the processing reservoir;
a process of measuring a flow rate flowing into a reservoir provided upstream or downstream of the processing reservoir;
A process of acquiring calibration information, which is information when the water quality measurement unit is calibrated, from the water quality measurement unit to be maintained;
Based on the water quality measured by the water quality measurement unit, the measured flow rate, the acquired calibration information, and the operation status of the water treatment device, a maintenance method for the water quality measurement unit for which the calibration information is acquired is determined. processing;
and a process of outputting information indicating the determined maintenance method.

In the present invention, maintenance can be performed by a method and timing suitable for usage conditions.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows 1st Embodiment of the water-quality measuring system of this invention. 2 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. 1; It is a figure which shows 2nd Embodiment of the water quality measuring system of this invention. 4 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. 3; It is a figure which shows 3rd Embodiment of the water quality measuring system of this invention. 6 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. 5; It is a figure which shows 4th Embodiment of the water-quality-measurement system of this invention. 8 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. 7; 8 is a diagram showing an example of a display screen displaying information indicating a maintenance method determined by the control unit shown in FIG. 7; FIG.

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. In addition, in the following description, a hydrogen ion exponent is called pH.

(First embodiment)
FIG. 1 is a diagram showing a first embodiment of the water quality measurement system of the present invention. As shown in FIG. 1, the water quality measurement system in this embodiment includes tanks 100, 120, 130, a water treatment device 110, water quality measurement units 140, 150, a flow rate measurement unit 160, a calibration information acquisition unit 170, a control and a portion 180 .
Tanks 100, 120, and 130 are water tanks (storage units) each having a predetermined capacity. The tank 100 is a tank (reservoir for treatment) in which the water to be treated that has flowed from the tank 120 is treated by the water treatment device 110 . The tank 120 is provided upstream of the tank 100 with respect to the flow direction of the water to be treated. The tank 130 is provided downstream of the tank 100 with respect to the flow direction of the water to be treated. The water treatment device 110 performs predetermined treatment such as purification on the water to be treated that has flowed in from the tank 120 . The water quality measurement unit 140 measures the water quality within the tank 120 . The water quality measurement unit 150 measures the water quality within the tank 130 . Examples of the water quality measurement units 140 and 150 include electrode-type instruments such as a pH meter and a fluorine meter, and spectral instruments such as a turbidity meter. The water quality measured by the water quality measuring units 140 and 150 relates to liquid properties such as temperature, viscosity, concentration of suspended matter and dissolved matter. The flow rate measuring unit 160 measures the flow rate flowing into the bath 120 . Note that the flow rate measured by the flow rate measurement unit 160 is the cumulative flow rate after maintenance of the water quality measurement unit is performed. Also, the flow rate measuring unit 160 may measure the flow rate of water flowing into the tank 130 provided downstream of the tank 100 instead of the flow rate of water flowing into the tank 120 provided upstream of the tank 100 . The calibration information acquisition unit 170 acquires the calibration information of the water quality measurement unit from among the water quality measurement units 140 and 150 that is subject to maintenance. This calibration information is information indicating the amount of voltage change and response time when the water quality measurement units 140 and 150 are calibrated, the date and time when maintenance was performed, and the maintenance history indicating the details of the maintenance. The control unit 180 selects the water quality measuring unit for which the maintenance method is determined from the water quality measurement results of the water quality measuring units 140 and 150, the flow rate measured by the flow rate measuring unit 160, and the calibration information acquired by the calibration information acquiring unit 170. and the operation status of the water treatment device 110, the calibration information acquisition unit 170 determines the maintenance method for the water quality measurement unit for which the calibration information has been acquired. Also, the control unit 180 outputs information indicating the determined maintenance method.
In the embodiment shown in FIG. 1, there is one tank 120 provided upstream of the tank 100 and one tank 130 provided downstream of the tank 100. However, each tank has a plurality of tanks. It may be provided. In this case, a water quality measurement unit is provided for each of the plurality of tanks, the calibration information acquisition unit 170 acquires calibration information from each water quality measurement unit, and the control unit 180 performs maintenance for each water quality measurement unit that has acquired the calibration information. It may determine the method.

A maintenance method determination method in the water quality measurement system shown in FIG. 1 will be described below.
FIG. 2 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. First, the water quality measurement unit 140 measures the water quality in the tank 120, which is the first tank (step S1). Also, the water quality measurement unit 150 measures the water quality in the tank 130, which is the second tank (step S2). Also, the flow rate measuring unit 160 measures the flow rate flowing into the tank 120 (step S3). Further, the calibration information acquisition unit 170 acquires calibration information indicating the maintenance history of each of the water quality measurement units 140 and 150 from each of the water quality measurement units 140 and 150 (step S4). The order in which steps S1 to S4 are performed is not specified. For example, the process of step S3 may be performed, then the process of step S4 may be performed, and then the processes of steps S1 and S2 may be performed, or the processes of steps S1 to S4 may be performed at the same timing. It can be.
Then, the control unit 180 selects the water quality measuring unit whose maintenance method is determined from among the measurement results of the water quality measuring units 140 and 150, the flow rate measured by the flow rate measuring unit 160, and the calibration information acquired by the calibration information acquiring unit 170. and the operation status of the water treatment device 110, the calibration information acquisition unit 170 determines a maintenance method for the water quality measurement unit for which the calibration information has been acquired (step S5). Subsequently, the control unit 180 outputs information indicating the determined maintenance method (step S6).

As described above, in the present embodiment, the calibration information of the water quality measurement unit to be maintained and the calibration information obtained through the tank containing the water to be treated in order for the water treatment apparatus to perform a predetermined treatment are obtained. A maintenance method for the water quality measuring unit to be maintained is determined based on the water quality measured by the water quality measuring unit facing the water quality measuring unit, the flow rate flowing into the system, and the operating status of the water treatment device. Therefore, it is possible to perform maintenance on the target water quality measuring unit in a manner and timing suitable for the usage conditions.

(Second embodiment)
FIG. 3 is a diagram showing a second embodiment of the water quality measurement system of the present invention. As shown in FIG. 3, the water quality measurement system in this embodiment includes tanks 100, 120, and 130, a water treatment device 110, water quality measurement units 140 and 150, a flow rate measurement unit 160, a calibration information acquisition unit 171, a control and a portion 181 . Tanks 100, 120, 130, water treatment device 110, water quality measuring units 140, 150, and flow rate measuring unit 160 are the same as those in the first embodiment.
The calibration information acquisition unit 171 acquires calibration information indicating the maintenance history of the water quality measurement unit 150 from the water quality measurement unit 150 . Based on the measurement result of water quality in the water quality measurement unit 140, the flow rate measured by the flow measurement unit 160, the calibration information acquired by the calibration information acquisition unit 171, and the operation status of the water treatment device 110, the control unit 181 A maintenance method for the water quality measurement unit 150 is determined. The control unit 181 controls the water quality measurement results of the water quality measurement units 140 and 150, the flow rate measured by the flow rate measurement unit 160, the calibration information acquired by the calibration information acquisition unit 171, and the operation status of the water treatment device 110. The maintenance method for the water quality measuring unit 150 may be determined based on the above. Also, the control unit 181 outputs information indicating the determined maintenance method.
In the embodiment shown in FIG. 3, there is one tank 120 provided upstream of the tank 100 and one tank 130 provided downstream of the tank 100. However, each tank has a plurality of tanks. It may be provided. In this case, a water quality measurement unit is provided for each of the plurality of tanks, and the calibration information acquisition unit 171 acquires calibration information from the water quality measurement units provided for each of the plurality of tanks arranged downstream of the tank 100, and controls the calibration information. The unit 181 may determine the maintenance method for each water quality measurement unit that has acquired calibration information.

A maintenance method determination method for the water quality measurement system shown in FIG. 3 will be described below.
FIG. 4 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. First, the water quality measurement unit 140 measures the water quality in the tank 120 (step S11). Also, the flow rate measuring unit 160 measures the flow rate flowing into the tank 120 (step S12). Further, the calibration information acquisition unit 171 acquires calibration information indicating the maintenance history of the water quality measurement unit 150 from the water quality measurement unit 150 (step S13). The order in which steps S11 to S13 are performed is not defined. For example, after performing the process of step S13, the processes of steps S11 and S12 may be performed, or the processes of steps S11 to S13 may be performed at the same timing.
Then, the control unit 181 obtains the measurement result in the water quality measurement unit 140, the flow rate measured by the flow measurement unit 160, the calibration information obtained by the calibration information acquisition unit 171 from the water quality measurement unit 150, and the operation status of the water treatment device 110. Based on and, the maintenance method of the water quality measuring unit 150 is determined (step S14). Subsequently, the control unit 181 outputs information indicating the determined maintenance method (step S15).

Thus, in the present embodiment, when the water quality measuring unit to be maintained is provided downstream of the tank containing the water to be treated in order for the water treatment apparatus to perform a predetermined treatment, Calibration information of the water quality measurement unit, water quality measured by the water quality measurement unit installed upstream of the tank containing the water to be treated in order for the water treatment equipment to perform the prescribed treatment, flow rate flowing into the system, and water treatment A maintenance method for the water quality measuring unit to be maintained is determined based on the operating status of the device. Therefore, it is possible to perform maintenance on the water quality measuring unit provided downstream in a manner and timing suitable for the usage conditions.

(Third Embodiment)
FIG. 5 is a diagram showing a third embodiment of the water quality measurement system of the present invention. As shown in FIG. 5, the water quality measurement system in this embodiment includes tanks 100, 120, and 130, a water treatment device 110, water quality measurement units 140 and 150, a flow rate measurement unit 160, a calibration information acquisition unit 172, a control and a portion 182 . Tanks 100, 120, 130, water treatment device 110, water quality measuring units 140, 150, and flow rate measuring unit 160 are the same as those in the first and second embodiments.
The calibration information acquisition unit 172 acquires calibration information indicating the maintenance history of the water quality measurement unit 140 from the water quality measurement unit 140 . The control unit 182 measures the water quality based on the measurement result in the water quality measurement unit 150, the flow rate measured by the flow measurement unit 160, the calibration information acquired by the calibration information acquisition unit 172, and the operation status of the water treatment device 110. A maintenance method for the unit 140 is determined. Note that the control unit 182 is based on the measurement results of the water quality measurement units 140 and 150, the flow rate measured by the flow measurement unit 160, the calibration information acquired by the calibration information acquisition unit 172, and the operation status of the water treatment device 110. The maintenance method for the water quality measuring section 140 may be determined by the above. The control unit 182 also outputs information indicating the determined maintenance method.
In the embodiment shown in FIG. 5, there is one tank 120 provided upstream of the tank 100 and one tank 130 provided downstream of the tank 100. However, each tank has a plurality of tanks. It may be provided. In this case, a water quality measurement unit is provided for each of the plurality of tanks, and the calibration information acquisition unit 172 acquires calibration information from the water quality measurement units provided for each of the plurality of tanks arranged upstream of the tank 100, and controls. The unit 182 may determine the maintenance method for each water quality measurement unit that has acquired calibration information.

A maintenance method determination method in the water quality measurement system shown in FIG. 5 will be described below.
FIG. 6 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. First, the water quality measurement unit 150 measures the water quality in the tank 130 (step S21). Also, the flow rate measuring unit 160 measures the flow rate flowing into the bath 120 (step S22). Further, the calibration information acquisition unit 172 acquires calibration information indicating the maintenance history of the water quality measurement unit 140 from the water quality measurement unit 140 (step S23). The order in which steps S21 to S23 are performed is not specified. For example, after performing the process of step S23, the processes of steps S21 and S22 may be performed, or the processes of steps S21 to S23 may be performed at the same timing.
Then, the control unit 182 obtains the measurement result in the water quality measurement unit 150, the flow rate measured by the flow measurement unit 160, the calibration information obtained by the calibration information acquisition unit 172 from the water quality measurement unit 140, and the operation status of the water treatment device 110. Then, a maintenance method for the water quality measurement unit 140 is determined (step S24). Subsequently, the control unit 182 outputs information indicating the determined maintenance method (step S25).

Thus, in this embodiment, when the water quality measuring unit to be maintained is provided upstream of the tank containing the water to be treated so that the water treatment apparatus performs a predetermined treatment, Calibration information of the water quality measurement unit, water quality measured by the water quality measurement unit installed downstream of the tank containing the water to be treated so that the water treatment equipment performs predetermined processing, flow rate flowing into the system, and water treatment A maintenance method for the water quality measuring unit to be maintained is determined based on the operating status of the device. Therefore, it is possible to perform maintenance on the target upstream water quality measuring unit by a method and timing suitable for the usage conditions.

(Fourth embodiment)
FIG. 7 is a diagram showing a fourth embodiment of the water quality measurement system of the present invention. As shown in FIG. 7, the water quality measurement system in this embodiment includes tanks 211 to 217 which are storage units, fluorine meters 221 and 227 which are water quality measurement units, a flow meter 231 which is a flow measurement unit, and a calibration information acquisition unit. 241, a controller 251, and pH meters 261, 262, 263, 266, and 268, which are water quality measuring units. Each role will be explained.

The tank 211 is a tank for sampling fluorine-containing waste water, which is raw waste water. A fluorine meter 221 measures the fluorine concentration of the raw water in the tank 211 . A pH adjuster such as dilute HCL (dilute hydrochloric acid)/dilute NaOH (dilute sodium hydroxide) is injected into the tank 211, and the pH meter 261 is used to adjust the pH of the waste water to 7, and the fluorine meter 221 measures the fluorine concentration of the raw water. Measure.
In the pretreatment, HCl is injected into the raw water to adjust the pH of the raw water. Specifically, HCL is injected to adjust the pH value of the raw water to 2 to 3, which is a value preset in the pH meter 268 . A tank may be provided for pretreatment.
A flow meter 231 measures the amount of raw wastewater flowing into tank 212 . It should be noted that the amount of raw waste water measured by the flow meter 231 is the cumulative flow rate after maintenance of the fluorine meter and the pH meter.
The tank 212 is a fluorine reaction tank for generating calcium fluoride (hereinafter referred to as CaF2). pH meter 262 measures the pH value of the water in bath 212 . In the tank 212 , slaked lime is injected into the tank 212 to adjust the pH value of the water in the tank 212 to 10 to 11, which is the value preset in the pH meter 262 .
The tank 213 is an AL reaction tank, and is a water tank for performing floc formation and AL adsorption of fluorine. pH meter 263 measures the pH value of the water in bath 213 . Dilute HCL/dilute NaOH is injected into the bath 213, and the pH value of the water in the bath 213 is adjusted to be 6 to 8, which is the value preset in the pH meter 263. Polyaluminum chloride ( PAC) is injected to flocculate the CaF2 produced in bath 212 . Also, some of the dissolved fluorine ions are adsorbed by AL.
The tank 214 is a flocculation tank into which a flocculating agent is injected to coarsen the flocs formed in the tank 213 .
The tank 215 is a sedimentation tank in which the flocs are sedimented and separated, and the supernatant (treated water) is overflowed to the subsequent stage. Also, the sludge that settles to the bottom is sent to the tank 216 or pulled out (discharged to the outside of the system).
The tank 216 is a sludge regeneration tank for dissolving (reusing) the AL sludge. pH meter 266 measures the pH value of the water in bath 216 . Slaked lime is injected into the tank 216 until the pH value of the water in the tank 216 reaches the preset value of 9-10 in the pH meter 266 to dissolve the AL sludge. Fluorine ions adsorbed on AL are reacted with slaked lime to generate CaF 2 , and the dissolved AL is sent to tank 213 .
A tank 217 is a treated water sampling tank for measuring the fluorine concentration of the treated water. A fluorine meter 227 measures the fluorine concentration of the treated water in the tank 217 .

A calibration information acquisition unit 241 acquires calibration information from the fluorine meters 221 and 227 . For example, prolonged use of the fluorine meters 221, 227 causes a phenomenon in which the values indicated by the fluorine meters 221, 227 deviate from the true fluorine concentration. In that case, the difference between the values indicated by the fluorine meters 221 and 227 and the true fluorine concentration is adjusted as a correction amount. Also, the calibration information acquisition unit 241 acquires calibration information from the pH meters 261 , 262 , 263 , 266 and 268 . For example, by using the pH meters 261, 262, 263, 266, and 268 for a long period of time, the potential difference between the internal liquid of the pH meters 261, 262, 263, 266, and 268 and the external water (to be measured) and , the relationship with the pH value is lost, and even if the pH values of the internal liquid and the external water are the same, a phenomenon occurs in which a potential difference occurs between them. In that case, the potential difference is adjusted as a correction amount. For example, even if the pH values are the same, if a potential difference of +30 mV occurs between them, the display of the pH value will be, for example, "5.50" instead of "7". In such a case, the correction voltage amount "+30 mV" when this "5.50" is calibrated to "7" becomes the correction amount. When such calibration is performed, the calibration information acquisition unit 241 acquires, as calibration information, a maintenance history that is a correspondence between the corrected value and the date on which the calibration was performed.

The control unit 251 acquires information indicating the fluorine concentration in the tank 211 from the fluorine meter 221 . The control unit 251 acquires information indicating the flow rate of raw water from the flow meter 231 . The control unit 251 acquires information indicating the injection amount of slaked lime into the tank 212 . The control unit 251 acquires information indicating the amount of PAC injected into the tank 213 . The control unit 251 acquires information indicating the injection amount of the coagulant into the tank 214 . The control unit 251 acquires information indicating the injection amount of slaked lime into the tank 216 . The control unit 251 acquires the calibration information acquired by the calibration information acquisition unit 241 . The control unit 251 controls the water quality (fluorine concentration) obtained from the fluorine meter 221 of the tank 211 arranged on the upstream side of the tanks 212 to 215, the flow rate obtained from the flow meter 231, and the calibration information obtaining unit 241. Based on the calibration information acquired from the fluorine meter 227 of the tank 217 arranged downstream of the tanks 212 to 215 and the operating status of the system, the tank 217 arranged on the downstream side of the tanks 212 to 215 Decide how to maintain the fluorine meter 227 . The control unit 251 controls the water quality (fluorine concentration) obtained from the fluorine meters 221 and 227, the flow rate obtained from the flow meter 231, and the calibration information obtaining unit 241. Based on the calibration information acquired from the fluorine meter 227 of the tank 217 and the operating status of the system, the maintenance method of the fluorine meter 227 of the tank 217 arranged downstream of the tanks 212 to 215 is determined. can be In addition, the control unit 251 controls the water quality (fluorine concentration) obtained from the fluorine meter 227 of the tank 217 arranged downstream of the tanks 212 to 215, the flow rate obtained from the flow meter 231, and the calibration information obtaining unit 241. Based on the calibration information acquired from the fluorine meter 221 of the tank 211 located upstream of the tanks 212 to 215 and the operating status of the system, the tank located upstream of the tanks 212 to 215 determine how to maintain the fluorine meter 221 of 211; The control unit 251 controls the water quality (fluorine concentration) obtained from the fluorine meters 221 and 227, the flow rate obtained from the flow meter 231, and the calibration information obtaining unit 241. Based on the calibration information acquired from the fluorine meter 221 of the tank 211 and the operating status of the system, a maintenance method for the fluorine meter 221 of the tank 211 arranged upstream of the tanks 212 to 215 is determined. can be The control unit 251 outputs information indicating the determined maintenance method. The control unit 251 multiplies the acquired water quality and flow rate to calculate the load amount. The control unit 251 determines a maintenance method based on the calculated load amount, the acquired calibration information, and the operating status of the system.

An example of operating conditions of the system in the form shown in FIG. 7 is shown below.
・Raw water flow rate: 25 m ³ /h
・Fluorine concentration: 400 to 600 mg/L
・Target treatment concentration: 8 m ³ /L or less ・Water tank capacity: tank 211: 0.5 m ³ , tank 212: 8 m ³ , tank 213: 5 m ³ , tank 214: 5 m ³ , tank 215: diameter 3.2 m, tank 216: ^1m3
・ Concentration of chemicals used: HCL: 35%, dilute HCL: 5%, dilute NaOH: 5%, slaked lime: 10%
・ Chemical injection amount: PAC: 300 mg / L, coagulant: 2 mg / L

A maintenance method determination method in the water quality measurement system shown in FIG. 7 will be described below. Here, an example of processing when the control unit 251 shown in FIG. 7 determines the maintenance method of the fluorine meter 227 will be described.
FIG. 8 is a flowchart for explaining an example of a maintenance method determination method in the water quality measurement system shown in FIG. First, the fluorine meter 221 measures the water quality (fluorine concentration) of the tank 211 (step S31). The control unit 251 acquires water quality information indicating the water quality measured by the fluorine meter 221 from the fluorine meter 221 . Also, the flow meter 231 measures the flow rate flowing into the bath 212 (step S32). The control unit 251 acquires from the flowmeter 231 flow rate information indicating the flow rate measured by the flowmeter 231 . Further, the calibration information acquisition unit 241 acquires calibration information indicating the maintenance history of the fluorine meter 227 from the fluorine meter 227 (step S33). The control unit 251 acquires the calibration information acquired by the calibration information acquisition unit 241 . Further, the fluorine meter 227 measures the water quality (fluorine concentration) of the tank 217 (step S34). The control unit 251 acquires water quality information indicating the water quality measured by the fluorine meter 227 from the fluorine meter 227 . The order in which steps S31 to S34 are performed is not specified. For example, after performing the process of step S33, the processes of steps S31, S32, and S34 may be performed, or the processes of steps S31 to S34 may be performed at the same timing.
Then, the control unit 251 multiplies the water quality indicated by the acquired water quality information and the flow rate indicated by the acquired flow rate information to calculate the load amount. Here, the water quality value indicated by the water quality information has a smaller value as the water quality is better (lower fluorine concentration), and a larger value as the water quality is poorer (higher fluorine concentration).
Subsequently, the control unit 251 determines the amount of HCL injected in the pretreatment, the amount of slaked lime and diluted HCl injected in the tank 212, the amount of PAC injected and diluted The injection amount of HCL, the injection amount of dilute NaOH, and the injection amount of the flocculant in tank 214 are calculated.
Subsequently, the control unit 251 determines a maintenance method for the fluorine meter 227 based on the calculated load amount, the calibration information acquired from the calibration information acquisition unit 241, and the operating status of the system (step S35). Subsequently, the control unit 251 displays information indicating the determined maintenance method (step S36).

FIG. 9 is a diagram showing an example of a display screen displaying information indicating the determined maintenance method by the control unit 251 shown in FIG. When the controller 251 decides to replace the fluorine meter 227 in the maintenance method, as shown in FIG. Display the display screen. In this manner, the control unit 251 displays, as a maintenance method, when maintenance is required and the content of the maintenance.

Several examples of determination of the maintenance method performed by the control unit 251 shown in FIG. 7 will be described below. Here, a case where the control unit 251 determines the maintenance method of the fluorine meter 227 will be described as an example. Further, the maintenance method determined by the control unit 251 includes the cleaning method of the water quality meter (liquid type used for cleaning, liquid volume, cleaning interval, cleaning time, brushing, immersion, etc.), calibration (timing), and replacement (timing). be done. The water quality measurement system of the present invention further has a cleaning unit that cleans the water quality measurement unit, and the control unit 251 determines the timing at which the cleaning unit cleans the water quality measurement unit as a maintenance method.

As a maintenance method, for example, the larger the value of the load amount calculated by the control unit 251, the larger the value indicated by the calibration information acquired by the control unit 251 from the calibration information acquisition unit 241, the greater the amount of maintenance for the entire system or the tank. The longer the continuous operation of water treatment is (the higher the operating rate), the more dirty the fluorine meter 227 is judged to be. Cleaning using a powerful cleaning liquid, cleaning with a short time interval between cleanings, and the like are determined as maintenance methods. On the other hand, the smaller the value of the load amount calculated by the control unit 251, or the smaller the value indicated by the calibration information acquired by the control unit 251 from the calibration information acquisition unit 241, the smaller the water treatment for the entire system or the tank. The longer the operation is stopped (lower the operating rate), the less dirty the fluorine meter 227 is determined. be. Also, the maintenance method may be determined based on the mutual balance and combination of the load amount, calibration information and operating status. For example, what kind of maintenance method is used when what value of load is acquired, what kind of maintenance method is used when what value of calibration information is acquired, and what kind of operation status The database may store in advance what kind of maintenance method is to be used. That is, the load amount, the calibration information, the operating status, and the maintenance method are associated with each other in advance and stored in the database, and the maintenance method is retrieved from the database using these information (values) acquired by the control unit 251 as search keys. It may be read out and determined. Also, the load amount, the calibration information, and the operating status may each be indicated using a score, and the maintenance method may be determined based on the sum of those scores. More specifically, the score corresponding to the value of the load amount obtained by multiplying the water quality (fluorine concentration) and the flow rate, the score corresponding to the value (correction) indicated by the calibration information, and the score corresponding to the operating status ( For example, the longer the operation time, the larger the value, the larger the value for outdoor use than for indoor use, the larger the difference between the ambient temperature and the specified temperature, the larger the value. The larger the amount of chemical injected into the tank, the larger the value, etc.) and based on the total score, the larger the total, the more intense the cleaning, even if it is cleaning or replacing the fluorine meter. Cleaning using a powerful cleaning liquid, cleaning with a short cleaning time interval, or the like may be determined as the maintenance method. The operating status may be the operating time after maintenance or the operating time during a certain period.

The maintenance method determined by the control unit 251 includes the content and timing of implementation, and is displayed to notify the outside, and is used as performance data for subsequent determination of the maintenance method. can be In that case, the timing and content of maintenance, which is actual data, and the results of using the maintenance method are associated and stored, and the database for determining the maintenance method is updated according to the level of the results. It can be anything. In addition, the control unit 251 may be a PLC (Programmable Logic Controller) that automatically controls the water treatment device, but it is not limited to that case. or a PC (Personal Computer) may be provided, and these may also serve as the functions. In addition, by implementing this control unit 251 in the cloud rather than at the site of water treatment to be controlled, if related data of other water treatment sites are also used, a more optimal maintenance method and timing can be determined. can also decide.

The calibration information acquisition unit 241 acquires the calibration information from each of the pH meters 261, 262, 263, 266, and 268, and the calibration information acquired by the calibration information acquisition unit 241 is acquired by the control unit 251. good. In this case, the control unit 251 determines the maintenance method of the pH meter from which the calibration information is obtained.

Also, the control unit 251 may transmit maintenance information indicating the determined maintenance method to an external device via a communication network or the like. If the external device to which the transmission is to be sent is equipped with a function for drafting a maintenance plan for the next year based on the maintenance information and ordering consumables, etc., the administrator who manages the system can use the device. Efficient in accomplishing them by using them. After implementing the displayed maintenance method, the administrator enters the method and implementation date into the apparatus as a result.

The present invention described above has the following effects.
(1) Meter cleaning can be optimized based on soiling data.
If dirt such as fluorine adheres to the electrodes of the meter, the measurement accuracy of the meter will be lowered (response time delay, measurement error, etc. will occur). Therefore, it is necessary to clean the meter periodically to maintain measurement accuracy. It is difficult to predict the amount of dirt that adheres to instruments because it is affected by many parameters, such as the type of wastewater, the amount of load, and the state of treatment. Therefore, in the present invention, based on the water quality/flow rate data and the configuration/operation data of the treatment equipment, the amount of dirt adhering to the meter is calculated, the appropriate cleaning timing and cleaning method are determined, and depending on the result perform additional cleaning. As a result, performance data can be recorded and analyzed together with the amount of change in voltage, response time, etc. of the instrument before and after cleaning. After that, by performing maintenance based on the data of the cleaning method determined up to the last time and the performance data after the actual cleaning, it is possible to predict dirt data with high accuracy.
(2) Degradation data can be used to optimize instrument calibration Instruments deteriorate according to the quality of the water being measured, the period of use, and the amount of cleaning. Therefore, periodic calibration is necessary in order to measure accurate values. Instrument aging, like cleaning, is affected by many parameters, making it difficult to predict the timing of calibration. Therefore, in the present invention, the deterioration data is calculated based on the water quality/flow rate data, the configuration/operation data of the treatment facility, and the cleaning performance of the instrument, and the appropriate calibration timing is determined. This makes it possible to record and analyze performance data together with the amount of change in voltage, response time, etc. of the instrument before and after calibration. Further, the timing of electrode replacement can be predicted based on the correction of voltage before and after calibration and the amount of change in response time.
(3) It is possible to improve the accuracy of replacement timing prediction based on the deterioration data and the calibration information.
Since the condition of the instrument cannot be confirmed without calibration, it is difficult to predict the timing of replacement in advance, and it is difficult to make an accurate guess until the timing (condition) to be calibrated approaches. Therefore, in the present invention, the replacement timing of the meter is predicted based on the deterioration data and the actual calibration information. Therefore, even if the instrument is almost new, it is possible to predict the replacement according to the usage environment.
(Other embodiments)

If the water quality measurement system has a learning function, the learning function may be used to determine the maintenance method. As a result of performing maintenance of the water quality meter using the maintenance method determined based on the data registered in the database described above, for example, it is determined whether the result was appropriate, and if it was appropriate, that The situation at that time and the maintenance method are stored as an appropriate association, and if they are not appropriate, the situation at that time and the maintenance method are stored as an inappropriate association. Such results may be accumulated as statistical information and used in the analysis phase of the learning function to determine a more appropriate maintenance method.

By using the learning function in this way, it is possible to more accurately determine an appropriate maintenance method for the water quality measuring unit according to the situation.

As described above, each function (process) is assigned to each component, but this assignment is not limited to the above. Moreover, the configurations of the constituent elements are also only examples, and are not limited to these. Moreover, what combined each embodiment may be used.

100, 120, 130, 211, 212, 213, 214, 215, 216, 217 tank 110 water treatment device 140, 150 water quality measurement unit 160 flow rate measurement unit 170 to 172, 241 calibration information acquisition unit 180 to 182, 251 control unit 221, 227 Fluorine meter 231 Flow meter 261, 262, 263, 266, 268 pH meter

Claims (9)

at least two water quality measuring units for measuring the quality of water in reservoirs respectively provided upstream and downstream of the treatment reservoir for the water treatment apparatus to perform a predetermined treatment on the water to be treated;
a flow rate measuring unit for measuring a flow rate flowing into a reservoir provided upstream or downstream of the processing reservoir;
a calibration information acquiring unit that acquires calibration information, which is information when the water quality measuring unit is calibrated, from the water quality measuring unit that is subject to maintenance;
Based on the measurement result in the water quality measurement unit, the flow rate measured by the flow rate measurement unit, the calibration information acquired by the calibration information acquisition unit, and the operation status of the water treatment device, the calibration information acquisition unit A water quality measurement system, comprising: a control unit that determines a maintenance method for the water quality measurement unit for which calibration information has been acquired, and outputs information indicating the determined maintenance method. In the water quality measurement system according to claim 1,
The calibration information acquisition unit acquires the calibration information from the water quality measurement unit provided downstream,
The control unit receives the measurement result from the water quality measurement unit provided upstream, the flow rate measured by the flow rate measurement unit, and the calibration information obtained from the water quality measurement unit provided downstream by the calibration information acquisition unit. , a water quality measurement system that determines the maintenance method based on the operating status of the water treatment equipment. In the water quality measurement system according to claim 1,
The calibration information acquisition unit acquires the calibration information from the water quality measurement unit provided upstream,
The control unit receives the measurement result from the water quality measurement unit provided downstream, the flow rate measured by the flow rate measurement unit, and the calibration information obtained from the water quality measurement unit provided upstream by the calibration information acquisition unit. , a water quality measurement system that determines the maintenance method based on the operating status of the water treatment equipment. In the water quality measurement system according to any one of claims 1 to 3,
The control unit calculates the load amount by multiplying the measurement result in the water quality measurement unit and the flow rate measured by the flow measurement unit, and the calculated load amount and the calibration information acquired by the calibration information acquisition unit. and a water quality measurement system that determines the maintenance method based on the operating status of the water treatment equipment. In the water quality measurement system according to any one of claims 1 to 4,
The water quality measurement system, wherein the control unit displays information indicating the determined maintenance method. In the water quality measurement system according to any one of claims 1 to 5,
further comprising a cleaning unit that cleans the water quality measuring unit;
The water quality measurement system, wherein the control unit determines timing for cleaning by the cleaning unit as the maintenance method. In the water quality measurement system according to any one of claims 1 to 6,
a database that associates and stores the load amount calculated by multiplying the measurement result and the flow rate, the calibration information, the operation status, and the maintenance method;
The control unit multiplies the measurement result in the water quality measurement unit and the flow rate measured by the flow measurement unit, the load amount calculated by multiplying, the calibration information acquired by the calibration information acquisition unit, and the operation of the water treatment device A water quality measurement system that reads out and determines a maintenance method from the database using the situation as a search key. In the water quality measurement system according to claim 7,
The control unit associates the determined maintenance method, the load amount, the calibration information, and the operating status used for determining the maintenance method with the maintenance method that is appropriate, or A water quality measurement system that stores inappropriate correspondence in the database, selects a more appropriate correspondence based on the correspondence, and determines the maintenance method. A process in which a first water quality measuring unit measures the water quality in a reservoir provided upstream of a treatment reservoir for the water treatment apparatus to perform a predetermined treatment on the water to be treated;
a process in which a second water quality measuring unit measures the water quality in a reservoir provided downstream of the processing reservoir;
a process of measuring a flow rate flowing into a reservoir provided upstream or downstream of the processing reservoir;
A process of acquiring calibration information, which is information when the water quality measurement unit is calibrated, from the water quality measurement unit to be maintained;
Based on the water quality measured by the water quality measurement unit, the measured flow rate, the acquired calibration information, and the operation status of the water treatment device, a maintenance method for the water quality measurement unit for which the calibration information is acquired is determined. processing;
and outputting information indicating the determined maintenance method.

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