KR20160092891A - System for integrated management of reservoir self-diagnosis - Google Patents

Abstract

The present invention relates to an integrated management system for a reservoir, capable of self-diagnosis, and more specifically, to an integrated management system for a reservoir, capable of self-diagnosis to diagnose abnormality of a device of measuring a water level, an overflowing rate, and a discharge rate by installing the multiple devices of measuring the water level, the overflowing rate, and the discharge rate and comparing multiple measurement values measured by the each device and to handle the abnormality in an initial stage. According to the present invention, the integrated management system for a reservoir capable of self-diagnosis includes: a water level measuring device for measuring the water level of the reservoir; an overflowing rate measuring device for measuring the amount of the water overflowing to an overflowing path of a reservoir bank; a reservoir management device for collecting and transferring information measured by the water level measuring device and the overflowing rate measuring device; and a manager server grasping the state of the reservoir by receiving the information transferred by the reservoir management device and processing the information and transferring the grasped state of the reservoir. The multiple water level measuring devices or the multiple overflowing rate measuring devices are installed at the same measurement position. The reservoir management device or the manager server compares a measurement value individually measured by the water level measuring devices or the overflowing rate measuring devices and determines whether a part of the water level measuring devices or the overflowing rate measuring devices has abnormality when a compared value is beyond a standard value. The reservoir management device or the manager server outputs or transfers the information in which there is the abnormality in a part of the water level measuring devices or the overflowing rate measuring devices.

Description

SYSTEM INTEGRATED MANAGEMENT OF RESERVOIR SELF-DIAGNOSIS < RTI ID = 0.0 >

The present invention relates to an integrated management system for a reservoir capable of self diagnosis, and more particularly, a plurality of apparatuses for measuring a reservoir water level, a filtrate amount and a discharge amount are provided, The present invention relates to an integrated management system for a reservoir capable of diagnosing an abnormality of a device for measuring the amount of water and a discharge amount and performing a self diagnosis.

In order to maintain the quality and quantity of agricultural products, irrigation is required to artificially supply deficient water from irrigation facilities such as reservoirs and pumping stations in addition to rainwater. In recent years, the need for scientific and efficient management of agricultural reservoirs due to frequent droughts and floods has been urgently needed in Korea, along with the global deepening of water shortage.

In addition to the agricultural water supply, which is the original function of the agricultural reservoir, it is essential to accurately measure the water level of the reservoir and the accumulated water volume in order to prevent flood prevention. Accurate and reliable low- Based on this, it is used as judgment data of water management by grasping the amount of water storage and the rate of water storage.

In order to maintain these reservoirs, many systems are installed and the reservoir management systems are introduced. Recently, the risk of natural disasters due to the collapse of reservoir dikes due to unusual weather is getting bigger.

Therefore, it is becoming increasingly necessary to monitor the state of the reservoir in real time, prepare for the risk situation, and quickly deploy it to the manager and the dangerous area.

Nonetheless, up to now, techniques for monitoring and managing the reservoir condition include Korean Patent No. 10-1032679 (a water level monitoring system using a pressure sensor in a sludge type reservoir), Korean Patent No. 10-1074586 The water level and the water quality of the reservoir are measured, and the water gate is controlled according to the measured water level to discharge the water. A system has been developed to such an extent that it is possible to reduce the size of the system.

The conventional technique for monitoring the reservoir condition has a disadvantage in that it can not detect the state of the reservoir water level and the amount of the reservoir even if a failure or abnormality occurs in the equipment.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and an object of the present invention is to provide a device for measuring a water level, a filtration amount and a discharge amount of a reservoir, The system is designed to diagnose the abnormality of the equipment for measuring the amount of water and the amount of discharged water, and to provide an integrated management system of a reservoir capable of self diagnosis.

In order to achieve the above object, the present invention provides an integrated management system for a pool capable of self-diagnosis, comprising: a water level meter for measuring a water level of a reservoir; a water level meter for measuring the amount of water overflowing the waterway of the reservoir; A reservoir controller for collecting and transmitting information measured by the water level meter and the water level meter, a reservoir controller for receiving information transmitted from the reservoir manager and processing the information to determine the reservoir state and transmitting the information, In the integrated management system, a plurality of the level meters or the drainage meters are provided at the same measurement position, and the reservoir manager or the manager server compares measurement values measured by each of the water level meter or the drainage meter, If the value exceeds the reference value, That the judgment of the level meter, or at least a portion of the instrument over quantity, and the pool manager or administrator server is characterized in that it transmits or receives information that at least some of the water level meter or the meter over quantity.

Further, the integrated pool management system capable of self-diagnosis according to the present invention may further include a collapse detector for measuring a change of the inclined slope of the reservoir, and the reservoir manager may store information on a slope change received from the collapse sensor, And the manager server determines from the information on the received slope change the possibility of collapse and collapse, the plurality of collapse detectors are provided at the same measurement location, The controller determines that there is an abnormality in some of the plurality of collapse detectors when the compared values are out of the reference value, and the reservoir manager or the manager server receives information indicating that some of the collapse detectors are abnormal Outputting or transmitting The.

In addition, the self-diagnosing reservoir integrated management system according to the present invention may further include a water flow meter for measuring a flow rate of water flowing through a water channel connected to a discharge port provided in the reservoir dam, The manager server transmits information on the flow rate of the water channel received from the measuring device to the manager server, and the manager server determines the degree of opening / closing of the water channel number installed in the water channel from the information on the flow rate of the received water channel, The reservoir manager or the manager server compares measured values measured by each of the plurality of water flow meter devices and if there is an abnormality in some of the plurality of water flow meter devices when the compared value deviates from the reference value And the reservoir manager or the manager server Is characterized in that information indicating that an abnormality exists in a part of the water flow meter is outputted or transmitted.

According to the present invention, there is provided a system for automatically managing reservoirs according to the present invention, comprising a plurality of equipments for measuring reservoir water level, filtrate amount and discharge amount, It is possible to diagnose the abnormality of the apparatus for measuring the amount of water and the amount of discharged water and to take measures early.

1 is a view conceptually showing a self-diagnosed pool integrated management system according to an embodiment of the present invention;
2 is a block diagram illustrating an integrated pool management system capable of self-diagnosis according to an embodiment of the present invention.
3 is a view showing an embodiment of a level gauge used in an integrated pool management system capable of self diagnosis according to an embodiment of the present invention
FIG. 4 is a cross-sectional view showing a reservoir gate and a discharge channel in a self-diagnosing capable reservoir integrated management system according to an embodiment of the present invention.
5A and 5B are diagrams illustrating an example of a collapse detector used in a self-diagnosed pool integrated management system according to an embodiment of the present invention
FIG. 6 is a sectional view showing another embodiment of the water level measuring device used in the self-diagnosing capable reservoir integrated management system according to the embodiment of the present invention
7A and 7B are perspective views showing the refracting portion of the water level meter shown in Fig.
Fig. 8 is a perspective view showing one end portion of the charging rod in the level gauge shown in Fig.
9A to 9E are graphs conceptually showing a change in water level for judging the possibility of collapse of a reservoir from a water level change in a self-diagnosed pool integrated management system according to an embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an integrated pool management system capable of self-diagnosis according to the present invention will be described in detail with reference to the embodiments shown in the drawings.

2 is a block diagram illustrating an integrated management system for a reservoir capable of self-diagnosis according to an embodiment of the present invention. Referring to FIG. 1, FIG. 3 is a view showing an embodiment of a level gauge used in an integrated pool management system that can be self-diagnosed according to an embodiment of the present invention. FIG. 4 is a flowchart illustrating a self- FIGS. 5A and 5B are views showing an example of a collapse detector used in a self-diagnosing capable reservoir management system according to an embodiment of the present invention. FIG. FIG. 6 is a view showing another embodiment of a level gauge used in a self-diagnosing capable reservoir management system according to an embodiment of the present invention. 7 is a perspective view showing a refracting portion of the level gauge shown in Fig. 6, Fig. 8 is a perspective view showing one end portion of the charging rod in the level gauge shown in Fig. 6, and Figs. 9A to 9E are cross- FIG. 2 is a graph conceptually illustrating a change in water level for determining a possibility of collapse of a reservoir from a change in water level in a self-diagnosed pool integrated management system according to an embodiment of the present invention. FIG.

1 is a block diagram showing an integrated management system for a reservoir according to the present invention. The integrated management system includes a manager server 70, a reservoir manager 30, a water level meter 10, a water level meter 20, a water flow meter 50, A collapse detector 60, a reservoir gate 40, a waterway gate 51, an administrator terminal 80, and an alarming device 90.

The level gauge 10 is for measuring the level of the reservoir. The water level meter 10 may be installed on the water surface of the reservoir to measure the height of the water surface of the reservoir by means of ultrasonic waves or a laser, or may measure the pressure of the water below the reservoir water surface to measure the water pressure.

That is, a method of measuring the height of the water surface of the reservoir by installing the ultrasonic sensor on the surface of the reservoir water to irradiate the water surface of the reservoir with ultrasound waves and receive the reflected ultrasonic waves may be used as the water level meter 10, An ultrasonic sensor (not shown in the figure) is mounted on the end of the 'A' shaped sensor mounting portion provided at the end of the observation bridge M extending from the reservoir bank B to the reservoir water surface so as to receive ultrasonic waves from the water surface An example of a method of measuring the height of the water surface of the reservoir by means of ultrasonic waves is provided on the upper part of the observation bridge M and a water level sensing control unit 12 for controlling the ultrasonic sensor and transmitting / receiving signals to / . The water level sensing control unit 12 may be configured to receive power from the outside as well as to have a separate solar power generation panel to store and use the power generated by the solar power generation.

In the meantime, as the level gauge, a pressure sensor for measuring the water pressure may be inserted below the water surface of the reservoir and a height of the water surface of the reservoir may be measured from the measured water pressure. In FIGS. 6 to 8, An example of the level gauge 100 configured to input the input rods 110 and 120 down the water surface of the reservoir along the slope of the reservoir dam and to input and remove the pressure sensor 150 through the inside of the input rods 110 and 120 .

6 to 8, the level gauge 100 using a pressure sensor includes a plurality of long-length input rods 110 and 120 installed along the slope of the reservoir bank B, one end of which is inserted below the water surface and installed on the slope of the reservoir bank, A sensor mounting pipe 140 connected to one end of the charging rod and a wire supporting part 143 provided inside the sensor mounting pipe so that both ends of the charging rod 110 and 120 are connected to the charging rods 110 and 120, A circulation wire 150 extending from the other end of the circulation wire 150 to the other end of the circulation wire 150. The circulation wire 150 is attached to the circulation wire 150, A pressure sensor which is placed below the water surface in a state of being accommodated in the mounting tube 140 and is moved from one end of the input rod 110 to the other end of the circulation wire 150 by the other circulation C2 of the circulation wire 150, (160). And the height of the reservoir water surface is measured from the water pressure measured by the pressure sensor 160, which is hung from the circulation wire 150 and injected below the reservoir water surface. Particularly, the input rods 110 and 120 are formed of a long tubular body, and the sensor mounting pipe 140 is connected to one end of the input rods 110 and 120 so that the circulating wire 150 is inserted into the pipes of the input rods 110 and 120, Lt; / RTI > The pressure sensor 160 suspended from the circulating wire 150 is connected to the sensor mounting portion 140 by circulating the other end portion 110 from one end 120 of the input rod 110 or 120 to the circulating wire 150, So that it can be taken out to the outside of the other end 110 of the input rods 110 and 120. That is, according to the present invention, the pressure sensor 160 is inserted into the sensor mounting portion 140 only by circulating the circulating wire 150 in a state where the input rods 110 and 120 are installed on the inclination of the reservoir bank B, And the pressure sensor 160 can be taken out of the water surface for maintenance.

The sensor mounting pipe 140 into which the pressure sensor 160 is inserted is formed with a flow hole 141a for circulating water around the tubular housing 141, The wire support portion 143 for catching the wire is formed. Meanwhile, an anchor 142 is formed to protrude from the sensor mounting pipe 140 to the bottom of the reservoir so that the charging rods 110 and 120 are not swayed from left to right when the charging rods 110 and 120 are inserted.

On the other hand, the inclined surface of the reservoir bank B on which the input rods 110 and 120 are installed is not constant in slope and becomes gradually gentler toward the bottom. Accordingly, when the input rods 110 and 120 are inserted into the inclined surface of the reservoir bank B, they are subjected to a bending force according to the inclination of the inclined surface. Accordingly, the present invention has a structure in which the refracting portion 130 is provided in the middle so that the charging rods 110 and 120 can be refracted along the slope of the reservoir where the inclination becomes gentler as the water depth becomes deeper. Referring to FIGS. 6 and 7, the refracting portion 130 connects the one end 120 and the other end 110 of the input rod to the separated positions. The refracting part 130 includes a first refracting tube 131 having a flange 131a for connecting the other end 110 of the introducing rod to one end and a first refracting tube 131 having one end 120 of the introducing rod connected to one end A refraction hinge 133 connected to the first refraction tube 131 and the second refraction tube 132 so as to rotate relative to each other and a second refraction tube 132 having a flange 132a for the refraction hinge 132, And a guide 134 for guiding the rotation of the second refraction tube 132 and the first refraction tube 131, which are relatively rotated about the second refraction tube 133. The guide 134 is formed in a circular arc shape in the second refraction tube 132 so as to correspond to the locus of rotation of the fin holder portion 131b and a pin fixing portion 131b provided in the first refraction tube 131. [ And a guide portion 132b having a guide slit.

The drainage amount measuring device 20 is for measuring the amount of water overflowing into the drainage passage F of the reservoir bank B. The water level meter 20 measures the level of water overflowing the freeness (F) and calculates the amount of water (that is, the amount of water) to be fished considering the cross section of the freeness (F). As in the case of measuring the water level of the reservoir, the water level meter 20 may be used to measure the water level of the water using an ultrasonic sensor. The present invention is characterized by predicting whether or not a dam breaks down as described below according to the amount of filtrate measured by the filtration quantity measuring device (20). In addition, the present invention provides information for allowing the water discharge meter 20 to readjust the instant measured as water starts to overflow the freeness (F) to a full water level.

The water flow meter 50 is configured to measure the amount of water flowing along the water channel P to control the amount of water supplied to the agricultural land or the like and is connected to the outlet O provided in the reservoir bank B And measures the flow rate of water flowing through the water channel P. The water flow meter 50 measures the water level of the water flowing through the water channel P by using an ultrasonic sensor as in the case of measuring the water level of the water reservoir and calculates the amount of water flowing through the water channel P May be used.

The collapse detector 60 detects the collapse of the reservoir dam B or a collapse of the reservoir damper B, and a plurality of collapse detectors 60 are installed on the inside or the slope of the reservoir dam B. Referring to FIG. 1, the collapse detector 60 is installed at a position where disruption is expected. As the collapse detector 60, various sensors may be used. 5A and 5B show examples of sensors constituting such a collapse detector. FIG. 5A shows an example of a method of detecting a collapse of a dam by sensing a slope change of the slope of the reservoir bank B using a tilt sensor. That is, the collapse detector 60 shown in FIG. 5A has a structure in which an angle sensor 61 capable of measuring the angle of inclination change is provided inside the closed housing 61. On the other hand, FIG. 5B shows an example of using a moisture sensor in order to detect leakage of water causing collapse of the reservoir bank B. That is, the collapse detector 60 'shown in FIG. 5B has a structure in which the energizing electrodes 62' are spaced apart from each other inside the housing 61 'opened downward, and the collapse detector 60' When the water flows into the lower inlet due to the falling of the water supply pipe 61 ', and electricity is supplied through the energizing electrode 61', it is detected whether the dam B is collapsed.

The reservoir manager 30 collects the information measured by the water level meter 10, the water flow meter 20, the water flow meter 50 and the collapse sensor 60 and transmits the collected information to the administrator server 70, And controls the opening and closing of the reservoir gate 40 and the waterway gate 51 in accordance with the information and the command received from the manager server 70. That is, the reservoir manager 30 not only transmits the information measured by the water level meter 10 and the water level meter 20 to the manager server 70, but also transmits the information of the water channel received from the water flow meter 50 Information about the flow rate and information about the inclined plane change received from the collapse detector 60 to the manager server 70. [

The administrator server 70 receives the information transmitted from the reservoir manager 30 and processes the information to determine the reservoir state and transmits the information to the administrator terminal 80 and the warning receiver 90. For example, the manager server 70 determines the possibility of collapse and collapse from information on the received slope change, and transmits the information to the administrator terminal 80 and the alarming device 90. In addition, the manager server 70 determines the degree of opening / closing of the number of water channels installed in the water channel from the information on the flow rate of the received water channel.

If it is detected by the water level meter 20 that the water level is started to be measured by the water level meter 20, the water level meter 10 or the administrator server 70 may change the water level measured by the water level meter 10 to the full water level Adjustment allows you to reset the values for water level and reservoir level.

On the other hand, if the manager server 70 deviates from the predicted change range of the water level change based on the rainfall amount of the area where the reservoir is installed, the information on the received reservoir water level change, and the information on the received water amount, the possibility of the collapse of the reservoir bank And judges that there is an error.

That is, the manager server 70 receives the information about the change of the reservoir water level measured by the water level meter 10, information about the amount of water measured by the water level meter 20, (Not shown in the drawings) or the precipitation amount information provided by the Korea Meteorological Administration, it is judged that there is a possibility of collapse of the reservoir dam if the change in the water level of the reservoir is out of the predicted change range .

In the meantime, the present invention is characterized in that the water level sensor 10, the water flow rate detector 20, the water flow rate meter 50, and the collapse sensor 60 are provided in two or more of the same measurement sites, So that the reservoir manager 30 or the manager server 70 can determine whether the detector is abnormal. 2, the sensor 1 and the sensor 2 are provided at the same measurement site in the case of the water level sensor 10, the water level sensor 20, the waterway flow meter 50 and the collapse sensor 60, If the measured value 1 is compared with the measured value 2 measured by the sensor 2 and the difference, ie, [measured value 1 - measured value 2], is greater than the set reference value, it is judged that there is an abnormality in the sensor or sensor. .

The reservoir gate 40 is a structure for controlling discharge of water through the discharge passage O formed in the reservoir bank B so as to be connected to the water channel P inside the reservoir bank B. Referring to the drawings, the reservoir gate 40 includes an inscription 41 for opening and closing an inlet of the discharge passage 0, a drive shaft 42 for transmitting opening and closing operations of the inscription 41, a drive shaft 42, A driver 43 such as a motor for driving the operation of the reservoir gate 30, information on the state of the reservoir gate 40 is transmitted to the reservoir manager 30, and an inscription A hydrological controller 44 for controlling the driving of the driver 43 to regulate the degree of opening and closing of the reservoir 41 and a support 45 provided on the slope of the reservoir bank B to support the drive shaft 42.

(P) of the water passage gate (51) is provided for each water passage (P) connected to the discharge passage (0). The waterway gate 51 transmits information about the degree of opening and closing of the waterway gate 51 to the reservoir manager 30 and receives information or commands from the reservoir manager 30 to open and close the reservoir manager 30.

9A to 9E are graphs showing an example of a case where there is a possibility of a reservoir bank collapse from an inflow amount due to reservoir water level, filtrate amount, discharge amount and precipitation. The amount of inflow into the reservoir by precipitation is difficult to measure accurately, but it is usually proportional to the amount of rainfall in the reservoir area, so the amount of inflow due to precipitation can be estimated or predicted. For example, when precipitation is present, data on the increase in water level can be collected several times, and the change in water level according to precipitation can be statistically estimated from the collected data. Therefore, the following description will explain the process of estimating the probability of the collapse of the reservoir dam from the change in water level by using a graph conceptually showing the predicted trend using the inflow amount estimated from the precipitation, .

9A is a graph showing the change in the level measured by the level gauge when the inflow amount due to precipitation = 0, the discharge amount = 0, the discharge amount = 0, or the inflow amount due to precipitation = to be. In this case, in the case of an abnormal state such as the collapse of the dam, that is, in the steady state (Ts), there is no change of the water level even after the passage of time, or the water level change is finely decreased by evaporation of water or natural reduction by absorption into the ground It is expected. However, when the water level is measured as the water level is decreased due to the increase of the water level beyond time range beyond the expected water level change range even though there is no other situation such as water discharge, there is a special situation such as the collapse of the reservoir dam . Accordingly, the manager server can notify the manager or the region (or the region) to check whether the reservoir bank collapses in the preliminary state Tp at which the water level decrease begins to increase or at the abnormal state Tc at which the water level suddenly decreases after the preliminary state Tp. We can warn residents.

Next, FIG. 9B is a graph showing the change in the water level measured by the water level measuring instrument when the inflow amount by the precipitation, the water amount, and the discharge amount = 0. In this case, it is expected that the steady state (Ts), when there is no abnormal condition such as the breakup of the dam, equilibrates the inflow amount and the filtrate amount over time and the water level is not changed or the water level is increased due to the inflow amount , The slope of the increase in water level is proportional to the difference between the inflow and the filtrate (inflow - filtrate). However, when the water level is measured as the water level is decreased due to the increase of the water level beyond time range beyond the expected water level change range even though there is no other situation such as water discharge, there is a special situation such as the collapse of the reservoir dam . Accordingly, the manager server can notify the manager or the region (or the region) to check whether the reservoir bank collapses in the preliminary state Tp at which the water level decrease begins to increase or at the abnormal state Tc at which the water level suddenly decreases after the preliminary state Tp. We can warn residents.

Next, FIG. 9C is a graph showing the change in the water level measured by the water level meter when the inflow amount by the precipitation is ≥ (the water amount + the discharge amount), the water amount is ≥0, and the discharge amount is> 0. In this case, although there is a difference in the slope of the water level change, since the water level change similar to that shown in FIG. 9B is shown, the flow amount due to the precipitation shown in FIG. 9C ≥ (water amount + discharge amount), water amount ≥0, A detailed description thereof will be omitted.

On the other hand, FIG. 9D is a graph showing the change in the water level measured by the water level meter when the amount of water flowed into the precipitation> 0, the water amount = 0, and the discharge amount = 0. In this case, although there is a difference in the slope of the water level change, since the water level change similar to that shown in Figs. 9B and 9C is shown, the detailed description of the case of the inflow amount> 0, the water amount = 0 and the discharge amount = 0 shown in Fig. 9D is omitted .

Lastly, FIG. 9D is a graph showing a change in the water level measured by the water level meter when the inflow amount by the precipitation, the discharge amount, and the water amount = 0. In this case, the slope of the water level change is proportional to the difference (flow rate - flow rate) between the flow rate and the flow rate because the flow rate is larger than the flow rate even after the lapse of time in the steady state (Ts) . However, when the water level is measured as the water level is decreased and the water level is suddenly decreased due to the passage of time beyond the expected water level change range even though there is no other situation such as the increase of the discharge amount, Can be expected. Accordingly, the manager server can notify the manager or the region (or the manager) to check whether the reservoir bank collapses in the preliminary state Tp at which the water level reduction rate begins to increase or at the abnormal state Tc at which the water level suddenly decreases after the preliminary state Tp. We can warn residents.

The administrator terminal 80 is a device that receives information related to the reservoir state transmitted by the manager server 70 and outputs the information on a screen or voice so that the administrator can confirm the information.

According to a signal received from the manager server 70, the warning broadcast unit 90 broadcasts a voice or a warning sound that can be heard by residents residing in a dangerous area when the reservoir collapses or discharges.

B Reservoir Weir
F Yeosu
O drainage
R river
P channel
M observation school
10 water level meter
20 water meter
30 Reservoir Manager
40 reservoir hydrology
50 water flow meter
60,60 'Collapse Detector
70 Manager Server
80 administrator terminal
90 Warning Broadcasting

Claims (3)

A water level meter for measuring the water level of the reservoir, a water level meter for measuring the amount of water overflowing the waterway of the reservoir dam, a reservoir manager for collecting and transmitting the information measured by the water level meter and the water level meter, 1. A system for managing integrated reservoirs, comprising: an administrator server for receiving information transmitted from a reservoir manager and processing the information to determine a reservoir state and transmitting the information;
Wherein the water level measuring instrument or the water flow rate measuring instrument is provided at a plurality of the same measuring positions,
The reservoir manager or the manager server compares the measured values measured by the water level meter or the plurality of water level meters, and when the compared value deviates from the reference value, it is judged that some of the water level meters or the water level meters are abnormal and,
Wherein the reservoir manager or the manager server outputs or transmits information indicating that some of the water level meter or the water level meter is abnormal. The method according to claim 1,
Further comprising a collapse detector for measuring a change in the slope of the reservoir dikes,
Wherein the reservoir manager transmits information on a slope change received from the collapse detector to the manager server,
Wherein the manager server determines from the information about the received slope change possibility the collapse possibility and the collapse,
The collapse detector is provided with a plurality of collision detectors at the same measurement position,
Wherein the reservoir manager or the manager server compares measured values measured by each of the plurality of collapse detectors and determines that some of the plurality of collapse detectors are abnormal when the compared value is out of the reference value,
Wherein the reservoir manager or the manager server outputs or transmits information indicating that some of the collapse detectors are abnormal. 3. The method according to claim 1 or 2,
A water flow meter for measuring a flow rate of water flowing through a water channel connected to an outlet of the reservoir,
Wherein the reservoir manager transmits information on the flow rate of the water channel received from the water flow meter to the manager server,
Wherein the manager server determines the degree of opening / closing of the number of water channels installed in the water channel from the information on the flow rate of the received water channel,
Wherein the plurality of water flow meter devices are provided at the same measurement position,
Wherein the reservoir manager or the manager server compares measurement values measured by each of the plurality of channel flowmeters and determines that there is an abnormality in a plurality of channel flowmeters when the compared value deviates from a reference value,
Wherein the reservoir manager or the manager server outputs or transmits information that some of the water flow meter is abnormal.

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