KR102100258B1 - Local communication apparatus for small scale water supply facility - Google Patents

Abstract

The present invention includes a first communication unit that receives sensor data from the sensor unit through a sensor network, and transmits sensor data to a smart switchboard, and a second communication unit that communicates with a monitoring web server that collects monitoring data of the smart switchboard through an IP network. Thus, a local communication device for a small water facility is disclosed, characterized in that data communication is performed using a redundant network including the sensor network and an IP network.

Description

LOCAL COMMUNICATION APPARATUS FOR SMALL SCALE WATER SUPPLY FACILITY

The present invention relates to a local communication device for a small-scale water supply facility, and more particularly, to transmit sensor data of a sensor unit to a smart switchboard through a sensor network, and communicate with a monitoring web server that collects monitoring data of the smart switchboard through an IP network. It relates to a local communication device.

Conventional small-scale water facilities raise the raw water of the well, which is a water source of the village, using an underwater motor, transfer it to a water tank of a drainage reservoir installed in the highlands of the village, and supply it to each family in the village through a water pipe connected to the water tank. The source water for the wells is groundwater, reservoir water, wells or valley water.

Conventional small-scale water supply facilities are formed in small-scale villages where water is not supplied through a wide-area water supply system, such as a rural village, a fishing village, or a mountainous village. For example, a conventional small-scale water facility is equipped with a water level sensor for detecting the water level of the water tank, and when the water level of the water tank is lowered, the water motor of the well is operated to maintain the water tank level above a certain level. .

The patent document relates to a small-scale water facility management system and its management method, which receives data from a water tank measuring device and a water tank measuring device that measures the amount of water stored in the water tank and transmits a water supply request signal to the water supply control device. It includes a communication device.

Conventionally, a control panel that controls a water facility controls underwater motors, controls power supply to the underwater motors and water level sensors, transmits communication control for receiving data from the water level sensors, and transmits the monitoring status of the water facilities to a web server or an administrator terminal. Since the communication control is performed, the manufacturing cost of the control panel can be increased by the multi-functional element on the control panel, and the possibility of malfunction may be increased due to the denseness of the functional elements on the control panel, and data can be obtained using SMS communication method of WCDMA. There is a problem in that the communication cost can be increased because it is transmitted and received.

Korean Registered Patent No. 10-1504074

In order to solve the above problems, the present invention provides a local communication device for a small water facility that communicates with a sensor unit used to precisely control a water facility in a smart switchboard and communicates with a web server collecting monitoring data of the switchboard.

A local communication device for a small-scale water supply facility according to an embodiment of the present invention for achieving the above object is smart through a first communication unit and an IP network that receives sensor data from the sensor unit through a sensor network and delivers the sensor data to a smart switchboard. And a second communication unit communicating with a monitoring web server collecting monitoring data of the switchboard, and performing data communication using a redundant network including the sensor network and an IP network.

The sensor unit may include one or more sensors that detect whether the circuit breaker is tripped, the overload condition of the underwater motor installed in the well, and the water level condition of the well and the water tank.

When the first communication unit detects a failure or an intrusion of a water facility through the sensor unit, the first communication unit may receive notification information from the smart switchboard, and the second communication unit may transmit the notification information to the IP communication device.

The second communication unit may include a CDMA modem or a serial network converter that supports TCP / IP.

The sensor unit may include a trip detection sensor that detects whether the circuit breaker trips in consideration of one or more of a circuit breaker's own defect, a line leakage current, and a line overcurrent.

The sensor unit may be characterized in that it comprises an EOCR sensor for sensing the overload condition of the underwater motor and a water level sensor installed in each well and water tank to detect the water level condition.

The water level sensor installed in the water tank may be characterized in that it comprises a self-generation means.

The sensor unit may be characterized by including a sensor for sensing the environment of the facility to detect the environment of the water facility.

The local communication device for a small-scale water supply facility according to another embodiment of the present invention receives the sensor data of the sensor unit through the sensor network, and receives the monitoring data of the smart switch panel through the first communication unit and the IP network that transmits the sensor data to the smart switch panel. It includes a second communication unit for communicating with the monitoring web server to collect, the second communication unit is characterized in that it receives the sensor data of the sensor for the environment sensing facility for detecting the surrounding environment among the sensors configured in the sensor unit.

The sensor for detecting the environment of a facility includes a complex sensing element composed of one or more sensing elements that detect the movement of an object in the surrounding environment, whether a door is opened and closed, and a sound, and includes an IP element that provides an IP network interface. can do.

The sensor for detecting the environment of the facility analyzes the possibility of an intrusion using sensor data generated from the composite sensing element, controls the imaging element to operate the imaging element included in the composite sensing element when it is determined that there is a possibility of intrusion, and the IP element It may be characterized in that it further comprises a control element for controlling the IP element to communicate with the second communication unit.

The present invention provides a local communication device for a small water supply facility that performs data communication using a redundant network including a sensor network and an IP network, thereby reducing the operation function of the smart switchboard and stably communicating with the sensor unit. It is possible to reduce the communication cost by providing packet-based data transmission and reception, and reuse the 3G network modem used in the existing 3G mobile communication as a local communication device, and reduce the manufacturing cost of the local communication device. have.

1 is a block diagram showing a management system for a small-scale water supply facility of the present invention.
FIG. 2 shows an example in which the sensor unit of FIG. 1 is disposed in a small water supply facility.
FIG. 3 is a block diagram showing the smart switchboard of FIG. 1 in detail.
FIG. 4 is an example showing in detail the display unit of FIG. 3.
5 is a block diagram illustrating in detail the local communication device of FIG. 1.
FIG. 6 shows the IP communication device of FIG. 1 in detail.
FIG. 7 is a block diagram showing the monitoring web server of FIG. 1 in detail.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings and the contents described in the accompanying drawings, but the present invention is not limited or limited by the embodiments.

1 is a block diagram showing a management system for a small water facility of the present invention, the management system for a small water facility includes a smart switchboard 100, a local communication device 200, a monitoring web server 300, and a local power supply 400. , Underwater motor 500, the sensor unit 600 and one or more of the IP communication device 700.

The smart switchboard 100 controls the operation of the underwater motor 500 by using the sensor data of the sensor unit 600, but receives power from the local power supply 400 and performs power supply and operation of the underwater motor 500. Control.

The smart switchboard 100 generates monitoring data for controlling the power supply and operation of the underwater motor 500, and the monitoring web server 300 collects monitoring data to remotely control or monitor the smart switchboard 100. .

The local communication device 200 receives the sensor data of the sensor unit 600 through the sensor network 10, transmits the sensor data to the smart switchboard 100, and the smart switchboard 100 through the IP network 20 It communicates with the monitoring web server 300 to collect the monitoring data.

When the local communication device 200 detects a failure or intrusion of a water facility through the sensor unit 600, it receives notification information from the smart switchboard 100 and transmits it to the IP communication device 700.

The IP communication device 700 may display the notification information through the display unit to provide notification information to the user in a small town, transmit the notification information to the user terminal, and notify the notification information through the broadcast unit.

The sensor unit 600 includes one or more sensors to detect whether the breaker is tripped, the state of the underwater motor installed in the well, and the water level state of the well and the water tank, and is disposed at a predetermined location in a small water facility, and the sensor network It is built.

FIG. 2 illustrates an example in which the sensor unit of FIG. 1 is disposed in a small-scale water supply facility, and the sensor unit 600 is installed in each well and a water tank to detect a water level, a sensor 601 for detecting water level, and an underwater motor ( And an electronic overload relay (EOCR) sensor 602 that detects an overload condition of 500).

The water level sensor 601 detects a high water level, a medium water level, a low water level, and a low water level based on the set water level threshold. The water level sensor 601 may include not only a water level sensing function but also a biological toxicity sensing function.

The water tank is a method in which raw water is supplied by a water pressure difference in which a well is located, and since it is disposed in a highland, there may be no obstacle to reduce solar heat. In addition, the water tank may be spaced apart from the smart switchboard 100 by a predetermined distance.

Conventionally, there is a problem in that the installation cost of the line increases by arranging a line for supplying power between the smart switchboard 100 and the water level sensor 601 installed in the water tank.

The present invention is characterized in that the solar self-generation means 450 is provided in the sensor 601 for detecting the water level of the water tank in consideration of the place where the water tank is disposed, reducing the installation cost of the line.

The EOCR sensor 602 is designed to detect heat when an overload of the underwater motor 500 occurs, to detect it, to become a semiconductor non-contact, so that the reaction speed is fast, the contact life is long, and it is designed to react to microcurrent.

The EOCR sensor 602 can detect a malfunction due to an abnormal power supply and damage due to a short state, as well as an overload of the underwater motor.

Since the underwater motor 500 converts and consumes electrical energy into kinetic energy, the power consumption is high, so it is supplied with power through a line connected from the smart switchboard 100, and the water level sensor 601 and EOCR sensor installed in the well are ( 602) is also supplied with power through a line connected from the smart switchboard 100.

The local power supply unit 400 is provided with a first line between the smart switchboards 100 to supply power to the smart switchboard 100, and the smart switchboards 100 have some of the underwater motor 500 and the sensor unit 600. Power is supplied to the sensor, and power can be supplied to the local communication device 200.

Since the local power supply 400 can be disposed close to the local communication device 200, power can be directly supplied to the local communication device 200.

The sensor unit 600 is disposed for each line and includes a sensor 603 for detecting a power failure on the line.

The blackout sensor 603 is combined including at least one of a resistor, a capacitor, and a rectifying diode, and detects a power outage by detecting a voltage or current flow in the line.

The smart switchboard 100 always receives power from the local power supply 400, controls the power supply of some sensors of the sensor unit 600 and the underwater motor 500, and is connected to the local power supply 400. If a power outage occurs on the line, the power of the spare battery is used.

Since the power failure detection sensor 603 detects whether a power failure occurs on the first line, power is supplied through a separate second line.

The sensor unit 600 includes a sensor 604 for sensing the environment of a facility that detects the surrounding environment of a water facility. The sensor 604 for detecting the environment of the facility is disposed in the local communication device 200 as illustrated in FIG. 2, but may be disposed around the smart switchboard 100, the local power supply device 100, or the water tank, and independently It may be arranged respectively, but is not limited thereto.

The sensor 604 for facility environment sensing includes a complex sensing element composed of one or more sensing elements that sense the movement of an object in the surrounding environment, whether a door is opened or closed, and a sound, and includes an IP element that provides an IP network interface.

The sensor 604 for detecting the environment of the facility is composed of a complex sensing element, and includes a control element for determining whether or not an intrusion of a water facility is generated, and the generated data is vast compared to other sensors.

The sensor 604 for facility environment detection is massive, and does not transmit data through the sensor network 10 because it is disposed close to the local communication device 200, but transmits data through the IP network.

The control element analyzes the possibility of intrusion using sensor data generated from the composite sensing element, and when it is determined that there is a possibility of intrusion, controls the imaging element to operate the imaging element included in the composite sensing element, and the IP element is a local communication device ( 200) to control the operation of the IP device. The composite sensing element can detect whether there is a fire or not, and may include a temperature element.

The sensor unit 600 includes a trip detection sensor 605 that detects whether or not the circuit breaker trips in consideration of one or more of the circuit breaker's own defect, line leakage current, and line overcurrent. The trip detection sensor 605 may be disposed around the smart switchboard 100 or the line.

3 is a block diagram showing in detail the smart switchboard of FIG. 1, the smart switchboard 100 includes a display unit 110, a breaker 120, a supply unit 130, a communication means 140, a storage unit 150, It includes one or more of the spare battery 160 and the control unit 170.

The control unit 170 uses the sensor data of the sensor unit 600 including one or more sensors to detect whether the breaker is tripped, the state of the underwater motor 500 installed in the well, and the water level state of the well and the water tank. Control the operation of 500.

The control unit 170 receives power from the local power supply 400 and controls power supply and operation of the underwater motor 500. The control unit 170 may receive power from the local power supply 400 and control power supply and operation of some sensors of the sensor unit 600.

The control unit 170 operates and controls the operation of the underwater motor 500 in an automatic mode in response to the water level state of the well and the water tank, but the trip of the breaker 120 or the underwater motor 500 during the operation of the underwater motor 500 When an overload occurs, the operation mode of the underwater motor 500 is changed to a manual mode or a stop mode.

The control unit 170 cuts off the power supply of the underwater motor when changing to the stop mode. The reason for changing to the stop mode is because of the overload, malfunction or line failure of the underwater motor 500, or because the water tank has a high water level.

In the present invention, when the underwater motor 500 breaks down, it can be operated manually, so emergency measures are possible, and the manager can determine the failure situation without visiting the site and maintenance is possible.

Upon receiving the manager's selection input, the control unit 170 performs self-diagnosis, including whether there is a power failure on the line and whether or not the breaker trips. The manager's selection input may be received through the input unit formed on the display unit 110 or may be received from the local communication device 200 through the communication unit 140. The local communication device 200 may receive a selection input from the monitoring web server 300 or the administrator terminal.

The present invention periodically detects the presence or absence of abnormal operation by receiving sensor data from the sensor unit 600, but performs self-diagnosis to collectively receive and analyze sensor data from the sensor unit 600 to accurately measure the abnormal operation. can do.

The control unit 170 calculates the water remaining amount of the water tank with reference to the data of the sensor 601 for detecting the water level in the water tank, and compares the water demand and the water remaining amount of the water tank. The storage unit 150 stores an algorithm for comparing the water demand and the remaining water amount.

The control unit 170 may compare the remaining water amount and the water demand of the water tank to calculate one of the rotation speed of the underwater motor 500 and a period during which repair / replacement service of the underwater motor 500 is available.

In the present invention, the administrator does not reside in the countryside of a small water facility, and since it is generally located in the city center, it takes a long time from the city center to the small countryside, and it is difficult to adjust the schedule of the manager, so the manager can repair / replace the underwater motor. Let me know to improve work efficiency. In addition, the present invention can prevent the overload of the underwater motor by controlling the rotational speed of the underwater motor by comparing the water remaining amount and the water demand of the water tank. In addition, the present invention does not simply use the water level sensor 601 as a water level detection, but can be further utilized to calculate an overload prevention or repair / replacement service period of the underwater motor.

The controller 170 receives sensor data from a local communication device 200 that provides a communication interface with the web server 300 for transmitting or receiving sensor data.

The control unit 170 receives power from the local power supply unit 400 and controls the supply unit 130 that supplies power to the underwater motor 500, the local communication device 200, or the sensor unit 600.

The supply unit 130 receives power from the local power supply unit 400 at all times, and when a power failure occurs on the first line connected to the local power supply unit 400, the power supply of the spare battery 160 is used.

The control unit 170 may automatically control the valve of the water pipe connected to the water tank to supply water to each household in the village.

4 is an example showing in detail the display unit of FIG. 3, the display unit 110 includes a first display unit 111 displaying the operation of the sensor unit 600 and a second display unit displaying the operation of the underwater motor 500 (112), a third display unit 113 for displaying the operation mode of the underwater motor 500, a fourth display unit 114 for displaying the communication status of the local communication device 200, and a fifth display unit for displaying the status of the switchboard ( 115). The display unit 110 may display water levels of the well and the water tank.

The monitoring web server 300 may include a function of the display unit 110 of the smart switchboard 100, display it in a statistical or chart form, and display the monitoring status of the smart switchboard 100 for each village unit.

FIG. 5 is a block diagram illustrating the local communication device of FIG. 1 in detail, and the local communication device 200 includes a first communication unit 210, a second communication unit 220, and a controller 230.

The first communication unit 210 receives sensor data of the sensor unit 600 through the sensor network 10 and transmits the sensor data to the smart switchboard 100.

The second communication unit 220 communicates with the monitoring web server 300 that collects monitoring data of the smart switchboard 100 through the IP network 20.

When the first communication unit 210 detects a failure or intrusion of a water facility through the sensor unit 600, it receives notification information from the smart switchboard 100, and the second communication unit 220 transmits the notification information to the IP communication device do.

The second communication unit includes a CDMA modem or serial network converter that supports TCP / IP.

Conventionally, since data is transmitted and received using WCDMA's SMS communication method, the communication cost has been increased, but the present invention can reduce the communication cost by providing packet-based data transmission and reception.

The present invention can reuse the existing 3G network modem used in 3G mobile communication as a local communication device 200, reduce the manufacturing cost of the local communication device 200, and reduce the operation function of the smart switchboard. have.

In the present invention, the sensor network 10 is built to optimize the power consumption of the sensor unit 600, and the local communication device 200 is configured as a redundant network to stably transmit and receive data.

The second communication unit 220 receives sensor data of the sensor 604 for facility environment detection, which detects the surrounding environment, among sensors configured in the sensor unit 600.

The sensor 604 for facility environment sensing includes a complex sensing element composed of one or more sensing elements that sense the movement of an object in the surrounding environment, whether a door is opened or closed, and a sound, and includes an IP element that provides an IP network interface.

The sensor 604 for detecting the environment of the facility is composed of a complex sensing element, and includes a control element for determining whether or not an intrusion of a water facility is generated, and the generated data is vast compared to other sensors.

The sensor 604 for facility environment detection is massive, and does not transmit data through the sensor network 10 because it is disposed close to the local communication device 200, but transmits data through the IP network.

The controller 230 controls operations of the first communication unit 210 and the second communication unit 220 and may perform a gateway function of the sensor network.

FIG. 6 shows the IP communication device of FIG. 1 in detail, and the IP communication device 700 includes one of a reception unit 710, a display unit 720, a transmission unit 730, a broadcast unit 740, and a processor 750. Includes above. For example, the IP communication device 700 may be disposed in a town hall that is a public facility in the town.

The IP communication device 700 may display the notification information through the display unit 720 to provide notification information to the user in a small town, and transmit the notification information to the user terminal 800 through the transmission unit 730. In addition, notification information may be notified through the broadcast unit 740. The processor 750 controls the operation of each component.

The IP communication device 700 can be reused as a 3G network modem used for existing 3G mobile communication.

FIG. 7 is a block diagram showing the monitoring web server of FIG. 1 in detail, and the monitoring web server 300 includes a function of the display 110 of the smart switchboard 100 and can be displayed in the form of statistics or charts. , It is possible to display the monitoring status of the smart switchboard 100 for each village unit.

The monitoring web server 300 includes a communication unit 310, a monitoring unit 320, and a database 330.

The communication unit 310 receives sensor data and monitoring data from the local communication device 100, and the database 330 stores sensor data and monitoring data.

The monitoring unit 320 may generate monitoring information in the form of statistics or charts by analyzing sensor data or monitoring data, and the communication unit 310 may transmit the monitoring information to the manager desktop 900 or the manager terminal 950. .

The present invention reduces the load of the smart switchboard 100 by performing communication by sharing the communication with the sensor unit 600 in the local communication device 200, without performing communication with the sensor unit 600 in the smart switchboard 100 It is possible to reduce the possibility of malfunctions or defects of the smart switchboard 100, and even if malfunctions or defects of the smart switchboard 100 occur, the sensor data from the local communication device 200 in the monitoring web server 300 By receiving, it is possible to stably monitor the water supply facility.

The present invention includes a spare IP communication means (not shown) in the smart switchboard 100, and when the malfunction or defect occurs in the second communication unit 220 of the local communication device 200, the defect information for the local communication device 200 , By transmitting one or more of the sensor data and monitoring data to the monitoring web server 300 through the preliminary IP communication means, it is possible to stably monitor the water facility, and the administrator can quickly check the defect information to quickly check the local communication device 200 ) Can be repaired or replaced.

10: sensor network 20: IP network
100: smart switchboard 200: local communication device
300: monitoring web server 400: local power supply
500: underwater motor 600: sensor unit
700: IP communication device 800: user terminal
900: administrator desktop 950: administrator terminal

Claims (11)

A first communication unit for receiving the sensor data of the sensor unit through the sensor network, and transmits the sensor data to the smart switchboard and
And a second communication unit communicating with a monitoring web server collecting monitoring data of the smart switchboard through an IP network,
The sensor unit is a trip detection sensor that detects whether the breaker is tripped, an EOCR sensor that detects an overload condition of an underwater motor, a water level sensor that is installed in each well and a water tank to detect the water level, and the surrounding environment of a water facility. Includes sensors for detecting the environment of the facility to be detected,
The smart switchboard controls the operation of the underwater motor using the sensor data of the sensor unit, generates monitoring data for controlling the power supply and operation of the underwater motor,
The smart switchboard calculates the remaining amount of water in the water tank using the data of the water level sensor, compares the remaining amount of water in the water tank with the demand for water, calculates the available period for repair / replacement service of the underwater motor, and informs the administrator.
The second communication unit receives the sensor data of the sensor for detecting the environment of the facility among the sensors configured in the sensor unit through the IP network,
Local communication device for a small water facility, characterized in that for communicating with the sensor unit via the sensor network and the IP network. delete According to claim 1,
When the first communication unit detects a failure or intrusion of a water facility through the sensor unit, the communication unit receives notification information from the smart switchboard, and the second communication unit transmits the notification information to the IP communication device. According to claim 1,
The second communication unit includes a CDMA modem or a serial network converter that supports TCP / IP. delete delete According to claim 1,
The water level sensor installed in the water tank is a local communication device for a small water facility, characterized in that it comprises a self-generation means. delete delete According to claim 1,
The sensor for detecting the environment of a facility includes a complex sensing element composed of one or more sensing elements that detect the movement of an object in the surrounding environment, whether a door is opened or closed, and a sound, and includes an IP element that provides an IP network interface. Local communication device for small waterworks to do. The method of claim 10,
The sensor for detecting the environment of the facility analyzes the possibility of an intrusion using sensor data generated from the composite sensing element, controls the imaging element to operate the imaging element included in the composite sensing element when it is determined that there is a possibility of intrusion, and the IP element And a control element for controlling the IP element to communicate with the second communication unit.

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