KR19990064498A - Method and apparatus for a alarm in the rainfall automatically - Google Patents

Abstract

Method to generate different alarms according to the degree of rainfall exceeding the set value, to save data on rainfall and alarm data, and to automatically generate alarms during rainfall to control alarm occurrence even at a distance. An apparatus is disclosed. The rainfall value detected by the rain gauge of the superior station is compared with the comparison value set by the remote control unit of the control station, and an alarm generation command corresponding to the rainfall value is transmitted to the alarm station. The alarm station can prevent a disaster by generating an alarm corresponding to an alarm generation command transmitted from a remote control unit. In addition, the data processing unit monitors the remote control unit to display the rainfall value and alarm occurrence information of the superior station, and transmits the rainfall value and alarm occurrence information of the superior station to the monitoring station when requested by the monitoring station. By controlling, the alarm occurrence contents of the alarm station can be controlled.

Description

Method and apparatus for automatically generating alarms during rainfall {Method and apparatus for a alarm in the rainfall automatically}

The present invention relates to a system for generating an alarm during rainfall, and more particularly, to generate different alarms according to the degree of rainfall exceeding a set value, and to store data on the rainfall and alarm occurrence, The present invention relates to a method and apparatus for automatically generating an alarm during a rain that can control an alarm occurrence.

In general, in the high mountain areas in summer, heavy rains often result in heavy rains.In order to minimize the damages caused by heavy rains, rainwater monitoring systems have been installed to detect rainfall in mountain areas where heavy rains frequently occur. Preventing accidents by sounding emergency alarms during heavy rains. However, it is difficult to predict the guerrilla heavy rain that falls locally at the summit of a high mountain, and there is a problem that an accident due to heavy rain occurs in the lowlands of the mountain.

The present invention has been made in order to solve the above problems, an object of the present invention is to detect the rainfall generated in the mountainous region to alert the warning signal according to rainfall to climbers and people living in low areas can quickly notify the danger alarm It is to provide a method for automatically generating an alarm during a rain.

Another object of the present invention is to provide an apparatus for automatically generating an alarm during a rain, which is suitable for carrying out the method of automatically generating an alarm during a rain.

Another object of the present invention is to provide a method for detecting rainfall in a superior station and transmitting it to a control station, an alarm station and a monitoring station.

It is still another object of the present invention to provide a method for generating different alarms depending on the extent to which the rainfall value transmitted from the superior station exceeds a set value.

It is still another object of the present invention to provide a method for controlling operations of a superior station, an alarm station and a control station by a monitoring station.

1 is a block diagram schematically showing an apparatus for automatically generating an alarm during rainfall according to the present invention.

2 is a flow chart schematically showing a method for automatically generating an alarm during rainfall according to the present invention.

FIG. 3 is a detailed flowchart illustrating an operation performed in the tenth step S100 of FIG. 2.

FIG. 4 is a detailed flowchart illustrating an operation performed in step 20 of FIG. 2.

FIG. 5 is a flowchart illustrating an operation performed in operation 30 of FIG. 2 in detail.

FIG. 6 is a flowchart illustrating an operation performed in step 40 of FIG. 2 in detail.

FIG. 7 is a flowchart illustrating an operation performed in operation 50 of FIG. 2 in detail.

Explanation of symbols for main parts of the drawings

100: excellent station 110, 210: data transmission device

120: rain collecting device 122: rain measuring sensor

124: storage unit 200: alarm station

220: broadcasting device 300: control station

310: remote control unit 320: data processing unit

400: watch station

In order to achieve the above object, the present invention, the process of calculating the rainfall value by measuring the rainfall of the mountainous region, the process of comparing whether the calculated rainfall value is greater than the set Dow value, if the rainfall value is greater than the Dow value rainfall value to the control station And a step of temporarily storing the calculated rainfall value when the rainfall value is less than the Dow value, and transmitting the rainfall value and the equipment status to the control station when the transmission request is made. step; If the rainfall value and equipment status data are not transmitted from the superior station, requesting data transmission, analyzing the transmitted rainfall value, calculating the alarm situation, and sending the alarm generation command corresponding to the calculated alarm situation to the alarm station. Transmitting, receiving and storing alarm data from alarm station, adjusting the time of superior station, alarm station and monitoring station to coincide with each other, receiving rainfall value and equipment status of superior station and equipment status of alarm station A 20th step of generating a warning corresponding to the received rainfall value S by storing and updating the stored data; Generating an alarm according to the alarm generation command transmitted from the remote control unit, generating an alarm corresponding to the transmitted rainfall value if the operation of the remote control unit is not normal, requesting the status of the alarm station equipment and alarm data from the remote control unit. A thirtieth step of generating a warning corresponding to the rainfall value by performing the process of transmitting the request data; After receiving and updating the data from the remote control unit, increasing the counts one by one, transmitting the changed data to the monitoring station when the last updated rainfall value and alarm generation data are changed, and requesting the rainfall value and alarm generation data from the monitoring station. A step 40 of monitoring the operation of the remote control unit, if any; In automatic mode, the current time is adjusted to match the control station, the superior station and the alarm station, the rainfall value and the alarm information are received from the data processor, and the changed alarm is received if the changed information is received from the data processor. In the updating process, when a signal for controlling the data processing unit is input from the outside in the manual mode, the control unit transmits a signal for controlling the data processing unit to the data processing unit, and the 50th step monitors an alarm situation through the PC of the data processing unit. Provides a method to automatically generate alarms during rainfall.

In order to achieve the above another object, the present invention, a superior station for detecting the rainfall in the mountainous area, calculates the rainfall value, and stores the calculated rainfall value; A remote control unit for receiving a rainfall value S transmitted from a superior station, comparing and analyzing the received rainfall value S with a Dow value T, and transmitting an alarm generation command corresponding to the rainfall value S to the alarm station; A control station comprising a data processing unit for storing and displaying the rainfall value and the alarm generation command received by the remote control unit; A monitoring station for receiving a status of an alarm system from a data processing unit at a long distance and manually controlling the remote control unit through the data processing unit; In addition, the present invention provides an apparatus for automatically generating an alarm during a rainfall consisting of an alarm station generating the corresponding alarm according to the alarm generation command received from the remote control unit.

In addition, the superior station receives power from a power supply device consisting of a solar cell, a charge controller and a battery, and is provided with a data transmission device consisting of a remote control unit (RTU), a transceiver, an antenna, and an RF modem. It is composed of a rain collecting device consisting of a rain gauge measuring data and a storage for storing the data (Recorder).

In addition, the alarm station receives power from a power supply device consisting of a solar cell, a charge controller and a battery, and is provided with a data transmission device consisting of a remote control unit (RTU), a transceiver, an antenna and an RF modem, an amplifier, It consists of a broadcasting device consisting of a message generator, a microphone and a speaker.

In addition, the data processing unit constituting the control station is composed of a PC (PC) and a printer for inputting and displaying data, the remote control unit is composed of a control unit, a transceiver, an RF modem and an antenna, the data processing unit and the remote control unit is AC110 It is powered by a power supply that supplies / 220V.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

1 is a block diagram schematically showing an apparatus for automatically generating an alarm during a rain in the present invention, Figure 2 is a flow chart schematically showing a method for automatically generating an alarm during a rain in accordance with the present invention, Figure 3 FIG. 4 is a detailed flowchart illustrating the operation performed in the tenth step S100 of FIG. 2, and FIG. 4 is a detailed flowchart illustrating the operation performed in the 20th step S200 of FIG. 2. 6 is a flowchart illustrating in detail an operation performed in step S300, and FIG. 6 is a flowchart illustrating in detail an operation executed in step 40 of FIG. 2 (S400). FIG. 7 is a fifty step S500 of FIG. A detailed flowchart of the operation performed in.

Referring to Figure 1 describes a device for automatically generating a warning during rainfall, first, the superior station 100 is installed in various places in the mountainous region. The superior station 100 detects the rainfall in the installed place, calculates the rainfall value K in minutes, and stores the calculated rainfall value K in minutes in the storage unit 124. The superior station 100 receives power from a power supply 150 consisting of a solar cell (not shown), a charge controller (not shown), and a battery (not shown), and the superior station 100 is a remote control device. A data transmission device 110 including a control unit (RTU), a transceiver, an antenna, and an RF modem is provided, and a rain collecting device (120) including a rain gauge (122) and a storage (Recorder) 124 is provided. Rainfall is detected by the rain gauge 122 of the rain collecting device 120 and the rainfall value K is calculated in minutes, and the rainfall value K calculated by the rain gauge 122 is transmitted. The total rainfall value S during the time set by the control unit RTU of the device 110 is calculated. The total rainfall value S is compared with the set Dow value T. When the rainfall value S is greater than the Dow value T, the controller applies the Dow information and the rainfall value S to the remote control unit 310 and the alarm station 200 of the control station 300 through the transceiver and the RF modem. If the rainfall value S is smaller than the Dow value T, the rainfall value S is temporarily stored in the storage unit 124. In addition, the control unit transmits the data on the rainfall value (S) and the equipment status to the remote control unit 310 when the data request from the remote control unit 310.

In addition, the control station 300 is installed in the superior station 100 and the remote lowland. The control station 300 is composed of a remote control unit 310 and the data processing unit 320, the remote control unit 310 receives the rainfall value (S) transmitted from the superior station 100, the received rainfall value Comparing and analyzing the (S) with the reference value of the alarm generation and sends an alarm generation command corresponding to the rainfall value to the alarm station 200. If the rainfall value is not transmitted from the superior station 100, the remote control unit 310 requests the superior station 100 for data on the rainfall value and the equipment status. In addition, the data processing unit 320 is composed of a PC (322) and a printer receives a power supply from the power supply unit 350 for supplying AC110 / 220V, the rainfall value and the alarm received by the remote control unit 310 The generation command is stored and displayed on the PC (322).

In addition, a plurality of monitoring stations 400 are installed at a distance from the control station 300, the monitoring station 400 receives the status of the alarm generation command from the data processing unit 320, and manually the data processing unit 320 By controlling the remote control unit 310 to control the volume and period of the alarm generated from the alarm station 200.

In addition, the alarm station 200 generates the corresponding alarm through the speaker according to the alarm generation command transmitted from the remote control unit 310. That is, the alarm station 200 receives power from a power supply device 250 consisting of a solar cell, a charge controller and a battery, and a data transmission device consisting of a remote control unit (RTU), a transceiver, an antenna, and an RF modem. The 210 generates a corresponding alarm through the speaker that is the broadcasting device 220 according to the alarm generation command transmitted from the remote control unit 310. In addition, the alarm station 200 determines whether the remote control unit 310 is in a normal state, and if it is in an abnormal state, generates a corresponding alarm based on the rainfall value S received from the superior station 100 through the speaker.

Referring to FIGS. 2 to 7, a method of automatically generating an alarm during rainfall will be described. First, the tenth step S100 of calculating and transmitting a rainfall value from the superior station 100 will be described. The rainfall of the mountainous region is measured by the rain gauge 122, and the rainfall value K is stored in the minute unit, and the rainfall value S is calculated in the set time unit (for example, 1 hour). In the second process, the controller compares whether the rainfall value S calculated during the set time (eg, 1 hour) is greater than the set Dow value T. In the third process, when the rainfall value S is greater than the Dow value T, the Dow information including the rainfall value S is transmitted to the control station 300. In the fourth process, if the rainfall value S is less than the Dow value T, it is determined whether there is a transmission request to transmit data from the control station 300. In the fifth process, if there is a transmission request for data transmission from the control station 300, the rainfall value and the equipment status of the superior station 100 are transmitted to the control station 300.

In FIG. 3, various environmental variables and communication ports of the superior station 100 are initialized (S102), and it is determined 104 whether rain is detected from the rain gauge 122 that measures rainfall. When rain is detected from the rain gauge 122 in step 104, the rainfall value K measured in minutes is updated and counted and stored in the storage unit 124 (S106). The total rainfall value S is calculated from the rainfall value K measured during the set time (for example, 1 hour) following the step 106 (S106). At this time, the measurement unit of the rainfall measured by the rainfall measuring sensor 122 is 1mm and the rainfall unit K, which is calculated at intervals of 1 minute, is stored in the storage unit 124. After the rainfall value K is calculated in the above minute unit, the total rainfall value S is obtained by summing all the rainfall values K measured for 1 hour from 1 hour to the present. In step S108, it is determined whether the rainfall value S measured during the time (1 hour) set is greater than the set Dow value T (S110). When the total rainfall value S measured in step 110 is greater than the set Dow value T, the remote control unit 310 transmits the Dow information including the measured rainfall value S to the remote controller 310 (S112). That is, if the total rainfall (S) before the set time (1 hour) to the present is greater than the set Dow value (T) immediately transmits the rainfall value (S) and Dow information to the remote control unit 310 of the control station 300 . If the total rainfall value (S) measured in step 110 (S110) is less than the set Dow value (T), it is determined whether the data request signal is applied from the remote controller 310 (S114) and the data request signal did not come. If the data request signal is received, the remote control unit 310 transmits data data (a rainfall amount value and a state of equipment of a superior station) to the remote control unit 310 (S116).

In addition, referring to the 20th step (S200) that the alarm corresponding to the rainfall value received from the superior station 100 is generated in the remote control unit 310, the rainfall value and equipment from the superior station 100 in the first process If no data has been sent, request data transmission. In the second process, the alarm condition is calculated by analyzing the transmitted rainfall value. In the third process, an alarm generation command corresponding to the calculated alarm situation is transmitted to the alarm station 200. In the fourth process, alarm generation data is received from the alarm station 200 and stored.

In FIG. 4, various environmental variables and communication ports of the remote controller 310 are initialized (S202), and it is determined whether Dow information including the rainfall value S is received from the superior station 100 (S204). If Dow information is authorized from the superior station 100 in step 204 (S204), all the superior stations 100 request data of the rainfall value S (S206). That is, when Dow information is received from one of the superior stations 100, the rainfall value S measured by the other superior stations 100 should also be referred to, so that all the superior stations 100 request data on the rainfall value S. do. After the step S206, the rainfall value S received from each of the excellent stations 100 is analyzed (S208). That is, after comparing and analyzing the rainfall value (S) transmitted from each excellent station 100 and compares the Dow value (T). Next to step S208, it is determined whether to send an alarm generation command to the alarm station (S210). That is, if the rainfall value S is greater than the Dow value by analyzing the rainfall value S received from each of the excellent stations 100, the alarm generation command is transmitted to the alarm station 200. Includes a signal that causes the alarm station 200 to generate one of a boundary alert, an evacuation alert, or a clear alarm. If it is determined in step 210 that the alarm is to be generated (S210) transmits an alarm generation command to the alarm station 200 (S212). After the second step S212, data corresponding to the alarm generation result transmitted from the alarm station 200 is received and stored (S214). After step 214 (S214), each of the superior stations 100 and the alarm station 200 is called normally and requests data corresponding to the rainfall value and the alert content (S216). At this time, the data is transmitted from the plurality of superior stations 100 and the alarm station 200, even if the data is not transmitted from any one excellent station or alarm station is ignored. After the step 216 (S216) stores the data transmitted from each of the superior station 100 and the alarm station 200 (S218). In step S218, it is determined whether an alarm generation command is transmitted to the alarm station 200 (S220). That is, by regularly requesting data on the rainfall value (S) from each of the superior stations (100), the rainfall value (S) received from each of the superior stations (100) is analyzed, and then the rainfall value (S) is greater than the Dow value (T). If) is large, an alarm generation command should be transmitted to the alarm station 200 at this time. When it is determined in step 220 that an alarm is to be generated, an alarm generation command is transmitted to the alarm station 200 (S222). After step 222 (S222), the data corresponding to the alarm generation result transmitted from the alarm station 200 is received and stored (S224). After the step 224 (S224), the data processing unit 320 determines whether there is a data request (S226). If there is no data request from the data processing unit 320 in step 226 (S226), and repeats step 204 (S204), and if there is a data request from the data processing unit 320 transmits the data to the data processing unit 320 (S228). )do.

In addition, the 30th step (S300) of generating an alarm corresponding to the rainfall value in accordance with the alarm generation command transmitted from the remote control unit 310 in the alarm station 200, the first process from the remote control unit 310 Alarm is generated according to the alarm command sent. In the second process, the alarm generation contents are transmitted to the remote control unit 310. The third process transmits the request data to the remote control unit 310 when the remote control unit 310 requests the alarm station equipment status and alarm data.

In FIG. 5, various environmental variables and communication ports of the alarm station 200 are initialized (S302), and it is determined whether an alarm generation command is transmitted from the remote control unit 310 (S304). When the alarm generation command is transmitted in step 304, the remote controller 310 generates the requested alarm, and transmits the result of the alarm to the remote controller 310 (S306). At this time, if the alarm frequency is changed from the remote control unit 310 to the alarm station 200 while the alarm is generated in the alarm station 200, the alarm station 200 converts the alarm frequency to generate an alarm. In step 304, the alarm generation command is not transmitted, or after step 306 (S306), it is determined whether there is a request for data on the equipment status of the alarm station 200 from the remote control unit 310 (S308). )do. If there is no data request for the equipment status of the alarm station 200 from the remote control unit 310 in step 308 (S308) and repeats step 304 (S304), the equipment of the alarm station from the remote control unit 310 If there was a request for data on the status of the remote control unit 310 transmits the data on the equipment status of the alarm station 200 (S310).

In addition, referring to step 40 of monitoring the operation of the remote control unit 310 in the data processing unit 320 (S400), the first process receives data on the rainfall value and alarm information from the remote control unit 310 in real time. To increase the count by one. In the second process, the changed data is transmitted to the monitoring station when the last updated rainfall value and alarm data are changed. In the third process, if there is a request for rainfall value and alarm occurrence data from the monitoring station 400, the requested data is transmitted. In the fourth process, when a manual signal is applied from the monitoring station or a manual control signal is input by itself, the remote controller 310 is controlled according to the manual control signal.

In FIG. 6, various environmental variables and communication ports of the data processor 320 are initialized (S402), and the remote controller 310 requests data in real time (S404). In step S404, it is determined whether data corresponding to the requested rainfall value and the alarm content are received from the remote controller 310 (S406). If data corresponding to the rainfall value and the alarm content are received from the remote controller 310 in step 406 (S406), the received rainfall value S and the alarm information are stored (S408). It is determined whether the last alarm time and contents stored after the step 408 are changed (S410). If the last alarm time and contents stored in step 410 are changed, the changed contents are transmitted to the monitoring station 400 (S412). In step 406 (S406), no data is received, or in step 410 (S410), or in step 412 (S412), there is a data request for rainfall value and alarm information from the monitoring station 400. It is determined whether or not (S414). If there is a data request for the rainfall value and the alarm information from the monitoring station 400 in step 414 (S414), the data on the rainfall value and the alarm information is transmitted to the monitoring station 400 (S416). In step 414 (S414), it is determined whether there is no data request or manual control signal corresponding to a manual operation from the monitoring station 400 after step 416 (S416). If the manual control signal is not applied in step 418 (S418), it is determined whether the manual control signal corresponding to a manual operation is input in the data processing unit 320 itself (S420). If the manual control signal is applied in step 418 (S418) or the manual control signal is input in step 420 (S420), the remote control unit 310 is controlled according to the manual control signal (S422). That is, when the monitoring station 400 monitors the alarm occurrence situation and the total rainfall value S of the alarm station 200 and the alarm contents for the total rainfall value are not appropriate, the monitor manually controls the data processing unit 320 manually. When the signal is applied, the data processing unit 320 automatically controls the remote control unit 310 according to the manual control signal applied from the monitoring station 400 to change the alarm contents. On the contrary, when a manual control signal is input manually through a terminal (not shown) provided in the data processing unit 320, the data processing unit 320 controls the remote control unit 310 to automatically control the alarm station 200. It will change the alarm contents.

In addition, if the monitoring station 400 describes the step S500 of monitoring the alarm situation through the PC (PC) of the data processing unit 320, the first process is a regular call to the data processing unit 320 to request the data; After receiving the rainfall value and the alarm information from the data processing unit 320. In the second process, when the changed information is received from the data processor 320, the final alarm information is updated. In the third process, when a signal for controlling the data processor 320 is input from the outside in the manual mode, the signal for controlling the data processor 320 is transmitted to the data processor 320.

In FIG. 7, various environmental variables and communication ports of the monitoring station 400 are initialized (S502), and the data processor 320 is called normally to determine whether data is requested (S504). When the data is requested in step 504 (S504), the rainfall value S and the alarm information received from the data processor 320 are received (S506). In step 504, it is determined whether there is no data request or whether information changed from the data processing unit 320 is received after step 506 in step S506. If the changed information is received in step 508 (S508), the latest changed alarm information is updated and stored (S510). If the changed information is not received in step 508 (S508) or after step 510 (S510), the updated rainfall value S and alarm information are displayed on a display unit (not shown) of the monitoring station 400 (S512). do. After the step 512 (S512) it is determined whether a signal for controlling the data processor 320 from the outside has been input (S514). If a signal for controlling the data processor 320 is applied in operation 514 (S514), the signal for controlling the data processor 320 is transmitted to the data processor 320 (S516). That is, the monitoring station 400 analyzes the rainfall value received from the data processing unit 320 and the alarm occurrence data of the alarm station, and the monitoring station 400 corresponds to a more urgent situation than the alarm content generated from the alarm station 200. Manually transmits an emergency signal to the remote control unit 310 through the data processing unit 320. The remote controller 310 controls the alarm station 200 according to a control signal applied from the monitoring station 400 through the data processor 320 to speed up the generation period of the alarm sound, which is an alarm signal, or corresponds to an emergency situation. By generating an alarm to prevent the accident.

As described above, the present invention compares and analyzes the rainfall value detected by the rain gauge of the superior station with the comparison value set in the remote control unit of the control station, and transmits an alarm generation command corresponding to the rainfall value to the alarm station. do. The alarm station can prevent a disaster by generating an alarm corresponding to an alarm generation command transmitted from a remote control unit. In addition, the data processing unit monitors the remote control unit to display the rainfall value and alarm occurrence information of the superior station, and transmits the rainfall value and alarm occurrence information of the superior station to the monitoring station at the request of the monitoring station. The alarm occurrence contents of the alarm station can be controlled.

Claims (8)

A tenth step of calculating a rainfall value from a superior station and transmitting the rainfall value to a control station and an alarm station; A twenty step of analyzing, by a remote control unit of the control station, the total rainfall amount value S for a predetermined time received from the superior station and transmitting an alarm generation command corresponding to the total rainfall value S to the alarm station; Generating an alarm corresponding to an alarm generation command transmitted from the remote control unit at the alarm station; A step 40 of monitoring, by the data processing unit of the control station, displaying the rainfall value and the alarm content on the display unit and transmitting it to the monitoring station; And a 50th step of monitoring the alarm situation by receiving the total rainfall amount S and the alarm content received from the monitoring station through the data processing unit. The method of claim 1, wherein the tenth step comprises: initializing various environmental variables and communication ports of the superior station; Step 104 of determining whether rain is detected from the rain gauge; In step 106, when the rainfall is detected, updating and counting the rainfall value K measured in the minute unit and storing the measured rainfall value K in a storage unit; Calculating a total rainfall value S from the rainfall value K measured during the set time; A step 110 for determining whether the total rainfall value S is greater than the set Dow value T; Step 112, if the total rainfall value S is greater than the set Dow value T, transmitting the Dow information including the measured rainfall value S to the remote control unit; If the total rainfall value S is less than the set Dow value T, determining whether a data request signal is applied from the remote controller; And a step 116 of transmitting data data (rainfall value and equipment status of a superior station) to a remote control unit if a data request signal is received. The method of claim 1, wherein the step 20 includes: initializing various environment variables and communication ports of the remote control unit; A step 204 of determining whether Dow information including the rainfall value S has been received from the superior station; Step 206, if the Dow information is authorized from the superior station, requesting data of the rainfall value S from all the superior stations; Step 208, analyzing the rainfall value S received from each of the excellent stations; Determining whether to transmit an alarm generation command to an alarm station (210); If it is determined that the alarm is to be generated, step 212, which transmits an alarm generation command to the alarm station; Step 214, receiving and storing data corresponding to an alarm generation result transmitted from the alarm station; Step 216, calling each of the superior stations and the alarm station and requesting data corresponding to the rainfall value and the alert content; Step 218 of storing data transmitted from each of the excellent stations and the alarm station; A step 220 for determining whether to send an alarm generation command to an alarm station; If it is determined that the alarm should occur, step 222 of transmitting an alarm generating command to the alarm station; Step 224 of receiving and storing data corresponding to an alarm generation result transmitted from the alarm station; Step 226 of determining whether a data request is made by the data processing unit; And step 228 of transmitting data to the data processing unit when the data request is received from the data processing unit. The method of claim 1, wherein the step 30 comprises: step 302 of initializing various environmental variables and communication ports of an alarm station; Step 304, determining whether an alarm generation command has been transmitted from the remote control unit; A step 306 of generating an alarm requested from the remote control unit and transmitting a result of the alarm to the remote control unit if an alarm generation command has been transmitted; Step 308, determining whether there is a request for data on the equipment status of the alarm station from the remote control unit; And a step 310 of transmitting the data of the equipment status of the alarm station to the remote control if there is a request for the equipment status of the alarm station from the remote control unit. The method of claim 1, wherein the step 40 comprises: initializing various environment variables and communication ports of the data processor; Step 404 of requesting data in real time to the remote control unit; A step 406 of determining whether data corresponding to the requested rainfall value and the alarm content are received from the remote control unit; Step 408 of storing the received rainfall value S and alarm information when data corresponding to the rainfall value and the alarm content are received from the remote control unit; Determining whether the last saved alarm time and contents have been changed (step 410); If the last stored alarm time and contents have been changed, step 412 of transmitting the changed contents to the monitoring station; Step 414, determining whether there is a data request for the rainfall value and the alarm information from the monitoring station; Step 416, if there is a request for data on rainfall value and alarm information from the monitoring station, transmitting data on rainfall value and alarm information to the monitoring station; Step 418, determining whether a manual control signal corresponding to a manual operation is applied from the monitoring station; If the manual control signal is not applied, determining whether a manual control signal corresponding to a manual operation is input to the data processing unit (420); And step 422 of controlling the remote control unit according to the manual control signal when the manual control signal is applied from the monitoring station or the manual control signal is input from the data processing unit. The method of claim 1, wherein the step 50 comprises: initializing various environment variables and communication ports of the monitoring station; A step 504 of determining whether a request for data is made by calling a data processing unit regularly; Step 506 of receiving the rainfall value S and the alarm information received from the data processor if the data is requested; A step 508 of determining whether the changed information has been received from the data processing unit; Step 510 of updating and storing the last changed alarm information when the changed information is received; Step 512 of displaying the updated rainfall value S and alarm information; A step 514 of determining whether a signal for controlling the data processor is input from the outside; And if the signal for controlling the data processing unit is applied, transmitting a signal for controlling the data processing unit to the data processing unit. A rainwater station that detects rainfall in a mountainous area in minutes and calculates a total rainfall value in hours, and stores the calculated rainfall values in minutes and rainfall values in hours; Remote control unit receives rainfall value from the superior station in real time, compares the received rainfall value with the set value, and sends an alarm generation command suitable for the rainfall value to the alarm station, and the rainfall value and alarm information received by the remote control unit. A control station comprising a data processing unit for storing and displaying; A monitoring station that receives the operation status of the superior station, the alarm station, and the control station from the data processing unit at a long distance, and controls the alarm contents generated from the alarm station by controlling the remote control unit through the data processing unit manually in an emergency; And an alarm station that automatically generates an alarm in the event of a rain, the alarm station generating a corresponding alarm according to an alarm generation command received from the remote control unit. 8. The system of claim 7, wherein the control station, the superior station, and the alarm station exchange information wirelessly, the control station and the monitoring station exchange information by wire, and the monitor can manually change the alarm occurrence of the alarm station. In the case, the monitoring station inputs the changed alarm content manually to the data processing unit of the control station, or inputs the changed alarm content through the terminal provided in the data processing unit.