KR101530674B1 - Rainfall observation system with a rainfall measuring instrument checking and through the rain sensing rainfall measuring instrument check method - Google Patents

Abstract

The present invention relates to a rainfall observation system, and a method to check a precipitation gauge capable of intelligent self-diagnosis. A precipitation gauge performs self-diagnosis and stores checking history to be capable of instantly providing a checking result in case a request is requested from the outside. The rainfall observation system comprises: the precipitation gauge composed of a water collecting reservoir, a flow speed decelerating device, a rainfall sensing sensor, a conductive cup, a lead switch, a drain, and a control unit; a solenoid valve installed in a drainpipe supplying rainfall test water; an electromagnet temporarily turning on the lead switch; a data logger transmitting a rainfall counting signal to a remote place and transmitting a solenoid valve drive signal, a stepping motor drive signal, and an electromagnet drive signal; and a rainfall measurement management server generating a rainfall supply checking order, a conductive cup checking order, and a lead switch checking order to be transmitted to the data logger, processing whether there are defects of the precipitation gauge to be displayed and storing the signal received from the data logger.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rainfall measuring system and a rainfall measuring apparatus,

More particularly, the present invention relates to a rainfall-amount monitoring system having a rainfall-rate monitoring function and a rainfall-amount checking method using rainfall detection. More particularly, the rainfall- The present invention relates to a precipitation amount monitoring system having a rainfall amount checking function and a rainfall amount checking method using rainfall detection.

Precipitation refers to the amount of precipitation (rainfall) and the amount of snow (snowfall) falling on the surface in the atmosphere, collectively referred to as precipitation, and the observation of precipitation means collecting precipitation and converting the amount to height.

In general, a rain gauge is an instrument for measuring rainfall phenomenon (rain, snow, etc.) among meteorological phenomena occurring in the atmosphere, and usually receives rainwater in a cylinder having a diameter of 20 cm and measures its depth and displays it in mm.

There are various types of rain gauges for measuring rainfall such as low water type cylindrical rain gauges, low water type magnetic rain gauges, conduction type gauges, weight type gauges, load cell type gauges and the like. It is classified by volume method. Low water type cylindrical rain gauges and low water type self gauges are methods by volumetric measurement. Conductive gauges, weigh gauges, and load cell gaugers belong to the weight measurement method.

The conductivity type rain gauge calculates the precipitation amount using the number of conduction times of the metered conduction through the water inlet, and the weight type rain gauge calculates the amount of precipitation by measuring the weight of the introduced water through the water outlet will be..

In the prior art, the registration number 10-0973789, which was filed by the present applicant and registered as a patent, is provided with a system for observing precipitation and a method for checking precipitation.

The system for observing the rainfall amount includes a collecting device for collecting rain water, a flow rate reducing port provided at a lower portion of the collecting container to reduce the flow rate of water to be dropped, A drain switch for discharging the high-level material to the conduit cup; and a controller for counting pulses generated from the reed switch to calculate a precipitation amount And outputs a solenoid valve drive signal from the outside, a stepping motor drive signal from the outside in response to the conduction cup drive signal from the outside, and a reed switch drive signal from the outside to output an electromagnet drive signal, A rainfall gauge; A solenoid valve installed on a drain pipe for supplying precipitation to supply the precipitation test water under the control of the control unit; An electromagnet driven by control of the control unit to temporarily turn on the reed switch; And transmits a rainfall supply control signal, a conduction cup drive signal, and a reed switch drive signal to the control unit by receiving a rainfall supply check command, a conduction cup check command, and a reed switch check command from a remote place A data logger for transmitting data; A precipitation supply check command, a conduction cup check command, and a reed switch check command to check the precipitation amount received from the data logger and periodically check the precipitation amount in connection with the data logger, transmit the data to the data logger, And a precipitation measurement management server that receives a response signal for checking the rainfall gauge received from the logger and processes and displays the presence / absence of a failure of the rainfall gauge.

In the conventional conduction type rain gauge as described above, more than 95% of the domestic rain gauge observation market is operated as a conduction type rain gauge. It has a simple structure and excellent price measurement performance. On the other hand, since the output is confirmed only when it is conducted while no output is available in normal operation due to its operating characteristics, the output is confirmed only in case of rain. These characteristics are not allowed to be confirmed even if the fault occurs normally, and the fault is recognized only in the case of the rain.

In addition, even if the conductivity type rain gauge is normal, it is often impossible to measure the precipitation observation information due to a physical or logical problem in the communication through which the signal is transmitted. In this case, It is to ensure the stable operation in the event of precipitation by taking measures in advance.

The causes of the problem are the clogging of the rainfall gauges by the foreign object, the movement of the conduit does not work, the bad contact of the signal terminal, the IP change due to the office transfer, the communication line break due to the communication construction, and the IP recovery due to security.

The self-checking method uses a metering pump to reproduce the precipitation situation (heating cost and construction cost increase due to the freezing problem in winter), artificially conducts the conduction by using the motor and produces output by artificially using the electromagnet .

A) Whether precipitation is collected through the collection port (check whether the collection port is blocked)

B) Whether conduction occurs through metered conduction (conduction or non-conduction)

C) Whether the magnet moves along the conduction and generates an output (check whether the magnet and reed switch are operating)

D) Whether the generated output is well received in the data logger (terminal contact of the signal line and check for line abnormality)

E) Whether the data logger works well (check for data logger operation)

F) Whether the information is collected by the collection server (check for any abnormalities in the communication line and changes related to IP)

G) Whether the collected information is checked and correct (overall system reliability check)

The expected effect is to ensure maintenance efficiency through easy remote check function, to be able to quickly identify and deal with the occurrence of faults through periodic inspection, to secure the reliability of the precipitation monitoring system through periodic state management, to secure data validity through reliable system, It is possible to analyze environmental factors through instantaneous remote inspection in case of abnormal data collection.

The above-mentioned precipitation monitoring system and the rainfall gauge inspection method can be remotely inspected if the precipitation meter having the self-diagnosis function has an immediate command transmission. However, since it takes time (about 15 seconds) in order to perform self-diagnosis, it is not possible to use a 1: 1 system but a 1: N (server: rainfall meters) (15 seconds) to be received, it is cumulatively delayed by the number of configured systems. So far, it is operated by cumulative precipitation of 10 minutes, so it can be completed within 10 minutes. However, in order to jointly use data with the Korea Meteorological Administration, Reveal limits. (10 sites = 15 seconds = 150 seconds = 2 minutes and 30 seconds, so it takes more than 1 minute to install each of the 10 sites.) In the end, it is necessary to self-check the entire system operated within 1 minute and collect the results.

Observation System of Precipitation and Method of Checking Precipitation in a Precipitation System.

An object of the present invention is to provide a rainfall observation system and a rainfall observation system having a rainfall gauge checking function that allows a rainfall gauge to perform self-diagnosis by itself on a preset schedule, And a method for checking a rainfall amount by detecting the rainfall amount.

According to an aspect of the present invention, there is provided a rainfall observation system having a rainfall gauge checking function, including: a collecting device for collecting rain water; a flow rate relaxing device for relieving a flow rate of water, A rainfall sensor installed on the lower side of the flow rate relief port to sense water, a conductive cup which is tilted to one side of the rotation axis by the weight of the water dropped from the flow rate relief port, A drain port for draining a high-level material from the conduit cup; a pulse counting unit for counting pulses generated from the reed switch to measure a precipitation amount; and a solenoid valve driving signal is output And receives a driving cup driving signal from the outside to output a stepping motor driving signal, Precipitation-based and made of a control unit for outputting an electromagnetic drive signal loads the position drive signal; A solenoid valve installed on a drain pipe for supplying precipitation to supply the precipitation test water under the control of the control unit; An electromagnet driven by control of the control unit to temporarily turn on the reed switch; The control unit transmits a measured rainfall amount counting signal to a remote location and receives a rainfall supply check command, a conduction cup check command, and a reed switch check command from a remote location to transmit a solenoid valve drive signal, a stepping motor drive signal, A data logger; A precipitation supply check command, a conduction cup check command, and a reed switch check command to check the precipitation amount received from the data logger and periodically check the precipitation amount in connection with the data logger, transmit the data to the data logger, A rainfall measurement management server for receiving a response signal for checking the rainfall gauge received from the logger, processing and displaying the failure of the rainfall gauge, determining whether the rainfall sensor is detected through the control unit, ; And

According to the present invention, there is provided a rainfall gauge checking method using rainfall detection, comprising: a collecting device for collecting rain water; a flow rate relieving port provided at a lower portion of the collecting container to relieve a flow rate of water to be dropped; A rain sensor for detecting water; a conductive cup tilted toward the center of the rotary shaft by the weight of the water dropped from the flow rate mitigator; and a reed switch which is generated when the conductive cup is tilted and generates a pulse by a magnet A discharge port for draining a high-level object in the conductive cup; a pulse counting unit for counting pulses generated from the reed switch to measure the amount of precipitation; a solenoid valve drive signal is output from the outside in response to a rainwater supply control signal; And outputs a stepping motor drive signal, receives a reed switch drive signal from the outside, Precipitation system consisting of a force controller and; A solenoid valve installed on a drain pipe for supplying precipitation to supply the precipitation test water under the control of the control unit; An electromagnet driven by control of the control unit to temporarily turn on the reed switch; The control unit transmits a measured rainfall amount counting signal to a remote location and receives a rainfall supply check command, a conduction cup check command, and a reed switch check command from a remote location to transmit a solenoid valve drive signal, a stepping motor drive signal, A data logger; A precipitation supply check command, a conduction cup check command, and a reed switch check command to check the precipitation amount received from the data logger and periodically check the precipitation amount in connection with the data logger, transmit the data to the data logger, And a precipitation measurement management server for receiving the response signal for checking the rainfall gauge received from the logger and processing and displaying the failure of the rainfall gauge and storing the signal received from the data logger through the control unit The method comprising the steps of: setting a schedule set by the precipitation measurement management server to check three times a day; starting precipitation measurement on a set time schedule; Checking if it is raining or not if it is a time checking schedule, A step of checking whether a rainfall sensing sensor installed on the lower side of the flow rate relieving unit for sensing water is sensed; and a step of determining whether the rainfall sensing sensor is sensed, The method comprising the steps of: starting a self-check if it is not detected; storing and taking action of the check result after starting the self-check; terminating the check after storing and checking the check result; (1) to (3), and (3) if it is determined that there is a trend,

If the rainfall is detected in the rainfall sensing step, the process proceeds to the rainfall observation step. If the rainfall amount is observed, the function check proceeds to the normal phase. If the rainfall amount is not observed, the rainfall sensing time is sufficient to observe the precipitation amount Minute), and if the observation time is sufficient, it is determined that the function check is an error.

In the step of starting the additional function of the other embodiment, when the precipitation amount is observed in the precipitation amount observation step, the flow proceeds to the rainfall detection step, and if the rainfall detection is observed, the function confirmation proceeds to the normal step. If the rainfall detection is not observed, .

Wherein the step of starting the self-check includes: setting one of a rainfall meter check period, a reed switch check method, a conduction cup check method, and a rain water supply check method in the precipitation measurement management server; The method comprising the steps of: transmitting a reed switch check command to a data logger in a precipitation measurement management server if the rainfall gauge checking method is a reed switch check method; checking the rainfall measurement management server after receiving a reed switch check command in the data logger; Generating a pulse by causing the reed switch to be temporarily turned on by outputting an electromagnet drive signal for turning on the reed switch after transmitting the check command response signal to the control unit; When the reed switch is turned on to generate a pulse, the data logger receives the precipitation counting signal Receiving a rainfall amount counting signal from the rainfall measurement management server when the precipitation amount counting signal is received; transmitting a rainfall amount counting signal to the precipitation measurement management server when the rainfall amount counting signal is not received; A step of transmitting a check command signal to the data logger from the precipitation measurement management server and processing the data to be communicated with the precipitation measurement management server when the reed switch check command response signal is not received, The method comprising the steps of: transmitting a check command signal to a data logger in the precipitation measurement management server and searching for a precipitation counting signal when a reed switch check command response signal is received by the precipitation measurement management server; After the rainfall amount check result is processed as a normal state and the processed data is stored, A step of displaying on the monitor whether the rainfall amount measurement signal is not received, if the precipitation amount measurement signal is not received, detecting whether a precipitation amount measurement signal is received from the data logger in the precipitation measurement management server; Displaying the result of the processing on the monitor on the monitor when the rainfall gauging failure signal is received; processing the rainfall gauging faulty state in the precipitation gauging management server and displaying a rainfall gauging faulty state on the monitor; The method comprising the steps of:

The step of starting the self-check of another embodiment includes the steps of setting a rainfall gauge check period and a conduction cup check method in the precipitation measurement management server, and controlling the rainfall gauge checking method when the set rainfall gauge check period is reached, Sending a conduit cup check command to the data logger in the precipitation measurement management server if the cup check method is in operation; transmitting the conduit cup check command response signal to the precipitation measurement management server after receiving the conduit cup check command in the data logger; A step of outputting a stepping motor drive signal for rotating the electroconductive cup to the control unit after the transmission of the check command response signal so that the electroconduction cup is rotated by a preset angle to generate a pulse by turning on the reed switch; When a switch is turned on to generate a pulse, the data logger detects whether a precipitation counting signal is received from the control unit Transmitting a precipitation amount counting signal to the precipitation measurement management server when the precipitation amount counting signal is received, and transmitting a rainfall amount measurement failure signal to the precipitation measurement management server when the precipitation amount counting signal is not received A step in which the precipitation measurement management server transmits a check command signal to the data logger and then processes the precipitation measurement management server and the data in a state of poor communication between the precipitation measurement management server and the data when the conduit cup check command response signal is not received; Checking whether a precipitation counting signal is received when the precipitation measurement management server transmits a check command signal to the data logger and then receives a conduit cup check command response signal to the precipitation measurement management server; The results of the rainfall gauging are shown as normal. After storing the data, A step of displaying on the monitor whether the rainfall amount measuring signal is received or not when the precipitation amount measuring signal is not received; By the control unit and data, And displaying the result on a monitor; and when the rainfall gauge bad signal is received, processing the rainfall gauge bad state in the precipitation measurement management server and displaying a rainfall gauge bad state on the monitor.

The step of starting the self-check of another embodiment may further include the steps of: setting a rainfall gauge check period and a rainfall supply check mode in the precipitation measurement management server; and when the rainfall gauge check period is reached, Transmitting a precipitation supply check command to the data logger in the precipitation measurement management server if the precipitation supply inspection check system is in operation; and transmitting a precipitation supply inspection command response signal to the precipitation measurement management server after receiving the precipitation supply inspection command in the data logger And a solenoid valve driving signal for turning on the reed switch after transmitting the precipitation supply check command response signal is outputted to the control unit so that the solenoid valve is temporarily opened to supply the precipitation test water, A step of generating a pulse by turning on the reed switch, The data logger includes the steps of retrieving whether a precipitation counting signal is received from the control unit, transmitting a precipitation counting signal to the precipitation measurement management server when the precipitation amount counting signal is received, and when the precipitation counting signal is not received, Transmitting a rainfall measurement fault signal to the server; transmitting a check command signal to the data logger from the precipitation measurement management server; and when a rainfall supply inspection command response signal is not received, A step in which the precipitation measurement management server transmits a check command signal to a data logger and then a precipitation measurement management server detects whether a precipitation amount counting signal is received when a precipitation supply check command response signal is received; When the precipitation amount counting signal is received, the result of the rainfall amount check is treated as a normal state A step of displaying on the monitor that the rainfall gauge is in a steady state after storing the processed data, and a step of detecting whether a rainfall gauge bad signal is received from the data logger in the precipitation measurement management server when the precipitation amount counting signal is not received, Processing the rainwater gauging failure signal with the rainfall gauge control unit and the data and displaying it on the monitor when the rain gauging fault signal is not received; And displaying a rainfall gauge poor state on the monitor.

The present invention as described above has an effect that the rainfall gauge itself performs self-diagnosis according to a preset schedule, stores the inspection history, and immediately provides the latest inspection result when requested from outside.

In addition, it is possible to remotely maintain and manage the precipitation system to reduce the labor cost, to remotely check the precipitation system periodically, and to confirm the occurrence of the fault in advance, so that it can not measure the precipitation amount due to the failure of the precipitation system .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a precipitation monitoring system having a rainfall gauge checking function according to the present invention. FIG.
FIG. 2 is a flowchart for checking a rainfall gauge through rainfall detection according to the present invention. FIG.
3 is a flow chart illustrating the addition of rainfall detection according to the present invention.
FIG. 4 is a flowchart illustrating the addition of rainfall detection according to the present invention. FIG.
5 is a control flowchart of a precipitation measurement management server for periodically checking a rainfall gauge at a remote place according to the present invention.
FIG. 6 is a control flowchart of a rainfall amount gauge control unit for periodically checking a rainfall gauge at a remote place according to the present invention. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the invention can be embodied in a plurality of different forms and is not limited to the embodiments described. It should be noted that the embodiments of the present invention described below are only for explaining the spirit of the present invention to a person skilled in the art, and a detailed description of known functions and configurations of the present invention which may unnecessarily obscure the gist of the present invention It should be noted that it is omitted.
FIG. 2 is a flow chart for checking a rainfall gauge through rainfall detection according to the present invention. FIG. 3 is a flowchart illustrating a rainfall detection method according to an embodiment of the present invention. FIG. 5 is a flowchart illustrating a control process of a precipitation measurement management server for periodically checking a precipitation meter at a remote site according to an embodiment of the present invention. Referring to FIG. 4, And FIG. 6 is a control flowchart of the rainfall amount gauge control unit for periodically checking the rainfall gauge at a remote place according to the present invention.

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1 to 6, the rainfall gauge 100 of the precipitation amount observing system having the function of checking the precipitation amount is provided with a collecting device 1 for collecting the precipitation, A rainfall detection sensor 30 provided below the flow rate relief port 2 for detecting water and a water level sensor 30 for sensing the temperature of the water dropped from the flow rate relief port 2, A reed switch 4 that is switched on by a magnet when the conductive cup 3 is tilted and is turned on by a magnet to generate a pulse; A discharge port 5 for draining a high-level object from the reed switch 3, a pulse counting unit 5 for counting pulses generated from the reed switch 4, measuring the amount of precipitation, receiving a precipitation supply control signal from the outside and outputting a solenoid valve drive signal And from the outside, And a control unit 6 for receiving a drive signal to output a stepping motor drive signal and receiving an external reed switch drive signal to output an electromagnet drive signal.

An electromagnet 7 driven by control of the control unit 6 to turn on the reed switch 4 and a stepping motor driven by control of the control unit 6 to forcibly rotate the conductive cup 3, And a solenoid valve 9 installed on a drain pipe for supplying precipitation to temporarily supply the precipitation test object under the control of the control unit 6. [

The control unit 6 transmits a measured rainfall amount to a remote place and receives a rainfall supply check command, a conduction cup check command, and a reed switch check command from a remote place to output a solenoid valve drive signal, a stepping motor drive signal, A rainfall supply check command connected to the data logger 10 to check the rainfall value received from the data logger 10 and to periodically check the precipitation amount, A check command, and a reed switch check command to the data logger, receives a response signal for checking the rainfall gauges 100 received from the data logger 10, processes and displays the presence / absence of the rain gauges, And a precipitation measurement management server 20 for storing the signal received from the data logger 10 through the control unit 6 whether or not the sensor 30 is sensed.

The communication between the data logger 10 and the precipitation measurement management server 20 can be performed through an Internet connection, an optical Internet connection or a leased line connection via a modem and a PSTN, a wired system using a ISDN network, a cellular system, a PCS communication system, And can accommodate all wireless Internet access through a communication network.

The stepping motor 8 is mounted on a rotary shaft of the conductive cup 3 and is configured to engage with the driving gear to constitute a driven gear that rotates the conductive cup 3 forward or reverse by rotation of the driving gear. The stepping motor 8 temporarily rotates forward or backward under the control of the control unit 6. [

FIG. 2 is a flowchart for checking a rainfall-based rainfall monitoring system according to the present invention. In the rainfall amount monitoring system, the time schedule set by the precipitation measurement management server 20 is set to check three times a day A step 13 for checking whether rainfall is on or off when the set inspection schedule is 12 and a step 13 for checking whether rainfall is on or off when the set inspection schedule is 12, If it is determined that the rainfall sensor 30 has been detected, it is determined that the rainfall sensor 30 has been detected. If the rainfall sensor 30 is not detected A step 15 of starting self-check, a step 16 of storing and taking an inspection result through the start of the self-check, It is composed of steps to make the 17 steps to shut down the sword, can be stored in a self-diagnostic results and can immediately transmit the results of the recent inspection within a maximum of 12 hours during precipitation measurement management servers or external requests without delay.

As shown in FIG. 3, when the rainfall is detected in the rainfall sensing step 22, the operation proceeds to step 23, and if the precipitation amount is observed, the function check proceeds to the normal 25 step. If the precipitation amount is not observed, If the time is sufficient for observing the precipitation (30 minutes), proceed to step 24, and if the observation time is sufficient, the function check is judged as an error.

If the precipitation amount can not be observed even though the rainfall is detected in the above, the conductive cup 3 or the reed switch 4 performs an error process with a failure.

As shown in FIG. 4, in the step 31 of starting the additional function of the other embodiment, when the precipitation amount is observed in the precipitation amount observation step 32, the rainfall detection step 33 is performed. When the rainfall detection is observed, the function confirmation is proceeded to the normal step 34, And if not, it is determined that the function check is an error.

If there is no rainfall detection in the above, it is judged as an error condition and the precipitation observation value can be discarded. This may cause errors due to wind, external vibrations or shocks.

In the preferred embodiment of the present invention, the rainfall gauge performs the self-diagnosis according to the preset schedule by itself and stores the inspection history. In order to immediately provide the latest inspection result upon request from the outside, The precipitation measurement management server 20 is set so that the self-diagnosis setting schedule is checked three times a day (for example, first 08:00, second 16:00, and third 24:00).

The self-diagnosis setting schedule can be selected and set by the user in the precipitation measurement management server 20, and the set self-diagnosis schedule is transmitted to the data logger and finally transmitted to the precipitation amount control unit so that the self- will be.

In the above-described state, in the rainfall meter 100, if it is determined in step 12 that the rainfall amount is set to three times a day and the rainfall amount measurement is started in step 11, And if the check schedule is 'no', the flow goes to step 11 of starting the measurement of the amount of precipitation.

If it is determined in step 14 that the rainfall detection sensor 30 installed on the lower side of the flow rate relief port 2 for detecting water is detected through step 13, the process proceeds to the next schedule, and the rainfall detection sensor 30 ) Is not detected, perform step 15 to start the self-check.

If water is sensed by the rainfall sensor 30, it is determined that it is raining, and even if it is a self-diagnosis schedule based on the schedule, it is ignored. Judgment of rainy conditions can also be obtained from recent precipitation measurements.

In step 15, the self check is started and the check result is stored and taken in step 16. In step 17, the check result is stored and the check is terminated.

As described above, the self-diagnosis is intelligently performed by the self-diagnosis schedule and the result is stored. When the external request is made, the precipitation measurement management server 20 immediately receives the most recent inspection result, You can.

As described above, it is possible to make an immediate and intuitive decision by judging whether or not to start the inspection by the rainfall detection sensor 30.

In order to judge the rain condition, a rainfall detection sensor 30 installed below the flow rate relief port 2 installed inside the rainfall gauge 100 detects water to intuitively detect whether it is raining or not, If the duration of the state exceeds the threshold value, it is decided that it is a precipitation situation.

In the case of conventional conduction water meters, conduction cups were inevitable to be accommodated as unconditional precipitation values.

However, according to the present invention, a rainfall detection sensor (30) implemented to detect rainfall in the rainfall gauge (100) is installed to compensate for the existing problems of observing unconditional precipitation amount Intelligent precipitation can be observed by linking functions. Such as conduction due to the influence of external winds and conduction due to external impacts.

The user executes a program for checking the precipitation meter 100 of the present invention in the precipitation measurement management server 20 and selects the precipitation meter check period and the checking method, The checking period may be performed twice or three times per day, or may be arbitrarily set. The method of checking the rainfall gauge 100 includes the reed switch 4 check method, the conducting cup 3 check method, and the precipitation supply control method. Then, in step 102, the precipitation measurement management server 20 checks whether the set inspection period has been reached, and proceeds to step 103 if the inspection period is reached. In step 103, the precipitation measurement management server 20 checks whether it is set to the reed switch check mode, and proceeds to step 104 if it is set to the reed switch check mode. In step 104, a check command of the reed switch 4 is transmitted to the data logger 10, and the process proceeds to step 109. [ If the reed switch check method is not set in step 103, the precipitation measurement management server 20 proceeds to step 105. If the precipitation measurement management server 20 is set to the conduction cup 3 check mode, . In step 106, an instruction to check the conductive cup 3 is transmitted to the data logger 10, and the process proceeds to step 109. [ If it is not set to the conduction cup inspection mode in step 105, the process proceeds to step 107. In step 107, the precipitation measurement management server 20 checks whether the system is set to the precipitation supply control mode. In step 108, the precipitation measurement management server 20 transmits the data to the data logger 10 and proceeds to step 109. [ When the precipitation measurement management server 20 transmits one command from the inspection command of the reed switch 4, the conduit cup 3 check command, and the precipitation supply inspection command, the data logger 10 receives it. In step 201, the data logger 10 checks whether one command is received from the inspection command of the reed switch 4, the conduit cup 3 check command, and the precipitation supply check command. If the check command is received, In step 202, the data logger 10 transmits a check command response signal to the precipitation measurement management server 20.

In step 109, the precipitation measurement management server 20 checks whether a check command response signal is received from the data logger 10. If the check command response signal is not received, the precipitation measurement management server 20 proceeds to step 110. In step 110, the precipitation measurement management server 20 processes the rainfall measurement management server 20 and the data logger 10 as a communication failure state. At this time, the precipitation measurement management server 20 may alert and display on the monitor that the communication between the precipitation measurement management server 20 and the data logger 10 is in a bad state.

In step 202, the check command response signal is transmitted to the precipitation measurement management server 20. In step 203, the data logger 10 checks whether the command is a precipitation supply check command. If the command is a precipitation supply check command, In step 204, the data logger 10 transmits a solenoid valve control signal to drive the solenoid valve 9 so that the precipitation test water supplied to the drain pipe is supplied to the collecting container 1. When water is supplied to the water collecting container 1, the water collected in the water collecting container 1 is dropped into the flow rate relief port 2, the flow rate relief port 2 relaxes the flow rate of water, and falls into the conductive cup 3 . When the water falls from the flow rate relief port 2, the conductive cup 3 rotates by the weight of the water and drops the dropped water to the discharge port 5. At this time, when the conductive cup 3 rotates, a magnet (not shown) installed on the rotary shaft of the conductive cup 3 moves like a watch and temporarily switches on the reed switch 4 to generate a pulse. The control unit 6 counts pulses generated from the reed switch 4 to measure the amount of precipitation. However, when the outlet of the flow rate reducing port 12 is blocked when the precipitation test water is supplied by the solenoid valve 9, the precipitation test water does not fall into the conductive cup 14 or the rotating shaft of the conductive cup 14 rusts The conductive cup 14 does not rotate even if the precipitation test water falls from the flow rate relief port 2, and a faulty state in which no pulse is generated in the reed switch 4 occurs. Therefore, the control unit 6 temporarily drives the solenoid valve 9 to supply the test water for precipitation, and if the pulse is not generated from the reed switch 4, the control unit 6 determines that the precipitation amount is in a poor state.

If the command is not the precipitation supply check command in step 203, the flow advances to step 205 to check whether the command is a reed switch check command. If the command is a reed switch check command, In step 206, the data logger 10 outputs an electromagnet driving signal to the controller 6. At this time, the control unit 6 drives the electromagnet 7 to generate a magnetic force when a current flows through the electromagnet 7, thereby temporarily turning on the reed switch 4 installed close to the electromagnet 7 so that the reed switch 4 A pulse is generated. The control unit 6 counts pulses generated from the reed switch 4 to measure the amount of precipitation. However, when the electromagnet 7 is temporarily driven and the pulse is not generated from the reed switch 4, the control unit 6 judges that the precipitation amount is in a bad state.

If it is determined in step 205 that the reed switch is not the reed switch check command, the flow advances to step 207 to check whether the command is a conduit cup check command. In step 208, the data logger 10 outputs a stepping motor drive signal to the controller 6. At this time, the control unit 20 drives the stepping motor 8. When the stepping motor 8 is driven, the driving gear rotates and the rotational force of the driving gear is transmitted to the driven gear. When the driven gear rotates, the conductive cup 3 rotates and tilts. When the reed switch 4 is temporarily turned on by the magnet provided on the rotary shaft of the conductive cup 3, a pulse is generated in the reed switch 4 do. The control unit 6 counts pulses generated from the reed switch 4 to measure the amount of precipitation. However, the control unit 6 temporarily drives the stepping motor 8 and judges that the pulse is not generated from the reed switch 4, that is, the rainfall amount is in a poor state.

When a pulse is generated from the reed switch 4 in the above manner, the controller 6 counts pulses to measure the amount of precipitation. If no pulse is generated from the reed switch 4, At this time, when the pulse is generated from the reed switch 4, the control unit 6 outputs the precipitation amount counting signal to the data logger 10, and if the pulse is not generated from the reed switch 4, Signal to the data logger 10.

Accordingly, in step 209, the data logger 10 checks whether the precipitation amount counting signal is received, and if the precipitation amount counting signal is not received, the flow advances to step 210. In step 210, the data logger 10 transmits a rainfall gauges failure signal to the precipitation measurement management server 20.

However, if the precipitation counting signal is received in step 209, the data logger 10 transmits a precipitation counting signal to the precipitation measurement management server 20 in step 211.

Thus, in step 111, the precipitation measurement management server 20 checks whether the precipitation amount counting signal is received, and if the precipitation amount counting signal is not received, In step 112, the precipitation measurement management server 20 checks whether a rainfall gauge bad signal is received, and if a rainfall gauge bad signal is received, In step 114, the precipitation measurement management server 20 performs the precipitation amount poor processing and displays on the monitor a rainfall amount poor state.

However, if the rainfall gauge bad signal is not received in step 112, the precipitation measurement management server 20 proceeds to step 113 and processes it as a poor communication state between the precipitation measurement management server 20 and the data logger 10 and displays it on the monitor . However, when the precipitation amount counting signal is received in step 111, the process proceeds to step 115, and the result of the rainfall amount check is determined to be a normal state, and the result is stored in the data storage unit. In step 116, the precipitation measurement management server 20 displays on the monitor that it is in a normal state as a result of the rainfall gauge check, so that the administrator can check it.

As described above, the precipitation measurement management server 20 receives a check command for checking the rainfall gauges 100 periodically by the data logger 10, an inspection command for the conduit cup, To the data logger (10), receives the check result response signal, and can check and manage the operation state of the precipitation meter (100) remotely.

The present invention can instantly and intuitively determine whether to start the inspection by the rainfall sensor 30. In addition, the rainfall gauges 100 can perform the self-diagnosis by themselves on the basis of a preset schedule, store the inspection details, and immediately provide the latest inspection results when requested from outside.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, The present invention may employ various changes, modifications, and equivalents. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention.

1: collecting container 2: flow rate reducing port
3: Conductive cup 4: Reed switch
5: outlet 6:
7: Electromagnet 8: Stepping motor
9: Solenoid valve 10: Data logger
20: precipitation measurement management server 30: rainfall detection sensor

Claims (7)

A flow rate mitigation port for relieving the flow rate of water dropped on the lower portion of the collecting container; a rainfall sensor installed on the lower side of the flow rate reduction port for sensing water; A reed switch which is transmitted when the conductive cup is inclined and generates a pulse by a magnet; a drain port for draining a high-level material into the conductive cup; A stepping motor driving signal is outputted from the outside by receiving a conductive cup driving signal from the outside, and a stepping motor driving signal is outputted from the outside, A control unit for receiving the driving signal and outputting the electromagnet driving signal; A solenoid valve installed on a drain pipe for supplying precipitation to supply the precipitation test water under the control of the control unit; An electromagnet driven by control of the control unit to temporarily turn on the reed switch; The control unit transmits a measured rainfall amount counting signal to a remote location and receives a rainfall supply check command, a conduction cup check command, and a reed switch check command from a remote location to transmit a solenoid valve drive signal, a stepping motor drive signal, A data logger; A precipitation supply check command, a conduction cup check command, and a reed switch check command to check the precipitation amount received from the data logger and periodically check the precipitation amount in connection with the data logger, transmit the data to the data logger, A precipitation measurement management server for receiving a response signal for checking the rainfall gauge received from the logger and displaying the processed rainfall gauge in the rainfall gauge and storing the signal received from the data logger through the control unit; Wherein the rainfall amount monitoring system has a rainfall amount monitoring function. A flow rate mitigation port for relieving the flow rate of water dropped on the lower portion of the collecting container; a rainfall sensor installed on the lower side of the flow rate reduction port for sensing water; A reed switch which is transmitted when the conductive cup is inclined and generates a pulse by a magnet; a drain port for draining a high-level material into the conductive cup; A stepping motor driving signal is outputted from the outside by receiving a conductive cup driving signal from the outside, and a stepping motor driving signal is outputted from the outside, A control unit for receiving the driving signal and outputting the electromagnet driving signal; A solenoid valve installed on a drain pipe for supplying precipitation to supply the precipitation test water under the control of the control unit; An electromagnet driven by control of the control unit to temporarily turn on the reed switch; The control unit transmits a measured rainfall amount counting signal to a remote location and receives a rainfall supply check command, a conduction cup check command, and a reed switch check command from a remote location to transmit a solenoid valve drive signal, a stepping motor drive signal, A data logger; A precipitation supply check command, a conduction cup check command, and a reed switch check command to check the precipitation amount received from the data logger and periodically check the precipitation amount in connection with the data logger, transmit the data to the data logger, And a precipitation measurement management server for receiving the response signal for checking the rainfall gauge received from the logger and processing and displaying the failure of the rainfall gauge and storing the signal received from the data logger through the control unit The method comprising the steps of: setting a schedule set by the precipitation measurement management server to check three times a day; starting precipitation measurement on a set time schedule; Checking whether it is raining or not if it is an inspection schedule, A step of checking whether or not a rainfall sensing sensor installed on the lower side of the flow rate mitigating port for sensing water is sensed, and if the rainfall sensing sensor is sensed, it is judged that it is rainy and the rainfall sensing sensor is sensed A step of starting a self-check if it is determined that the self-check is started, a step of storing and taking a measure of the self-check after starting the self-check, And transmitting the latest inspection result to the server or the outside without delay time when the server or the external request is received. 3. The method of claim 2,
If the rainfall is detected in the rainfall sensing step, the process proceeds to the rainfall observation step. If the rainfall amount is observed, the function check proceeds to the normal phase. If the rainfall amount is not observed, the rainfall sensing time is sufficient to observe the precipitation amount Minute), and if the observation time is sufficient, the function check is determined as an error. 3. The method of claim 2,
In the step of starting the additional function, if the precipitation amount is observed in the precipitation amount monitoring step, the flow proceeds to the rainfall sensing step, and if the rainfall detection is observed, the function check proceeds to the normal step, and if the rainfall detection is not observed, Wherein the rainfall detection method comprises the steps of: 3. The method of claim 2,
Wherein the step of starting the self-check includes: setting one of a rainfall meter check period, a reed switch check method, a conduction cup check method, and a rain water supply check method in the precipitation measurement management server; The method comprising the steps of: transmitting a reed switch check command to a data logger in a precipitation measurement management server if the rainfall gauge checking method is a reed switch check method; checking the rainfall measurement management server after receiving a reed switch check command in the data logger; Generating a pulse by causing the reed switch to be temporarily turned on by outputting an electromagnet drive signal for turning on the reed switch after transmitting the check command response signal to the control unit; When the reed switch is turned on to generate a pulse, the data logger receives the precipitation counting signal Receiving a rainfall amount counting signal from the rainfall measurement management server when the precipitation amount counting signal is received; transmitting a rainfall amount counting signal to the precipitation measurement management server when the rainfall amount counting signal is not received; A step of transmitting a check command signal to the data logger from the precipitation measurement management server and processing the data to be communicated with the precipitation measurement management server when the reed switch check command response signal is not received, The method comprising the steps of: transmitting a check command signal to a data logger in the precipitation measurement management server and searching for a precipitation counting signal when a reed switch check command response signal is received by the precipitation measurement management server; After the precipitation amount check result is processed in the normal state and the processed data is stored, A step of displaying on the monitor whether the rainfall amount measurement signal is not received, if the precipitation amount measurement signal is not received, detecting whether a precipitation amount measurement signal is received from the data logger in the precipitation measurement management server; Displaying the result of the processing on the monitor on the monitor when the rainfall gauging failure signal is received; processing the rainfall gauging faulty state in the precipitation gauging management server and displaying a rainfall gauging faulty state on the monitor; Wherein the rainfall detection method comprises the steps of: 3. The method of claim 2,
Wherein the step of starting the self-check includes: setting a rainfall gauge check period and a conduction cup check method in the precipitation measurement management server; and when the rainfall gauge check period is reached, Transmitting a conduit cup check command response signal to the precipitation measurement management server after receiving the conduit cup check command in the data logger; Outputting a stepping motor drive signal for rotating the electroconductive cup to the control unit after the check command response signal is transmitted to cause the electroconduction cup to rotate by a preset angle so that the reed switch is turned on to generate a pulse; When the pulse is generated, the data logger retrieves whether the precipitation counting signal is received from the control unit, Transmitting a rainfall counting signal to the rainfall measurement management server when the rainfall counting signal is received; transmitting a rainfall gauging failure signal to the rainfall measurement management server when the rainfall counting signal is not received; A step in which the server transmits a check command signal to a data logger and then processes the data in the intermittent communication failure state with the data of the precipitation measurement management server and the data when the conduit cup check command response signal is not received; The method comprising: transmitting a check command signal to the data logger and then detecting whether a precipitation counting signal is received when a response to the conduit cup check command is received by the precipitation measurement management server; And stores the processed data. Then, it is determined that the precipitation amount is in a normal state The method of claim 1, further comprising the steps of: when the precipitation amount counting signal is not received, searching the precipitation measurement management server to determine whether a rainfall amount gauging signal is received from a data logger; And displaying the result on the monitor when the rainfall gauge bad signal is received; processing the rainfall gauge bad state in the precipitation measurement management server when the rain gauge bad signal is received; and displaying the rain gauge bad state on the monitor A method for checking precipitation by rainfall detection. 3. The method of claim 2,
Wherein the step of initiating the self-check includes: setting a rainfall gauge check period and a rainfall supply check mode in the precipitation measurement management server; and when the rainfall gauge check period reaches the set rainfall gauge check period, Transmitting a rainfall supply check command response signal to the rainfall measurement management server after receiving a rainfall supply check command in the data logger; After the response signal is transmitted, a solenoid valve drive signal for turning on the reed switch is outputted to the control unit, and the solenoid valve is temporarily opened to supply the test water for precipitation. The reed switch is turned on by the conducting cup to turn on the pulse And when the reed switch is on and a pulse is generated, the data logger Detecting whether a precipitation counting signal is received from a fisher unit; transmitting a precipitation counting signal to the precipitation measurement management server when the precipitation amount counting signal is received; and if the precipitation amount counting signal is not received, The method of claim 1, further comprising the steps of: transmitting a fault signal to the data logger; transmitting a check command signal to the data logger from the precipitation measurement management server; The method comprising the steps of: transmitting a check command signal to a data logger at the precipitation measurement management server, and detecting whether a precipitation counting signal is received when a precipitation supply check command response signal is received by the precipitation measurement management server; When a signal is received, the result of the rainfall gauge check is treated as a normal state, and the processed data A step of displaying on the monitor that the rainfall gauge is in a steady state after storing the rainfall gauge gauge; and if the rainfall gauge counting signal is not received, detecting whether a rainfall gauge failure signal is received from the data logger in the precipitation measurement management server, When the rainfall gauging failure signal is received, processing the rainfall gauge to a bad state and processing the rainfall gauge to a monitor, And displaying a faulty state of the rainfall sensing unit.

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