KR20120034955A - Wireless type underwater monitering system using solar energy - Google Patents

Abstract

PURPOSE: A wireless underground water monitoring system using solar energy is provided to enhance the efficiency of maintenance, management, and utilization by observing a water level and state change of underground water on real time because observation data is wirelessly received from a remote site. CONSTITUTION: A wireless underground water monitoring system using solar energy comprises an underground water measuring unit(20), an automatic measurement main box(30), a solar light electricity feeding device(40), and a monitoring device(50). The underground water measuring unit is inserted into a measuring instrument, thereby measuring one or more among a water quality, a state, and a water level of underground water. The automatic measurement main box stores a measurement result by receiving from the underground water measuring unit via a wire or wireless. The solar light electricity feeding device converts solar energy into an electric energy, thereby supplying to the automatic measurement main box. The monitoring device receives information wirelessly transmitted from the automatic measurement main box, thereby monitoring the water quality, the state, and the water level of the underground water.

Description

Wireless groundwater monitoring system using solar energy {Wireless type underwater monitering system using solar energy}

The present invention relates to a groundwater monitoring system for monitoring by measuring the state of the groundwater, water quality, water level and the like.

In general, groundwater is water that reaches a layer where part of the rainfall penetrates into the soil gap from the surface and does not penetrate the water.

Such groundwater can be contaminated by wastewater from nearby factories, gas stations, livestock farms, pollutants, and many other sources.

In order to observe the degree of contamination (or change in condition) of groundwater, a manual observation method is generally used in which a groundwater well is drilled in the area where the groundwater is located and observation equipment is installed on the site.

In the manual observation method, observation devices are inserted into a well at regular intervals, and then the observation information is recorded.

However, such a manual observation method requires a small amount of observation cost because the equipment is installed on site and directly observed, but since the measurement is performed periodically or intermittently, the groundwater level and state change are continuously identified. It is difficult to do so, there is a problem that the groundwater measurement management is not easy.

In particular, if the observation well is installed in a secluded remote place, it is not easy to measure the water quality and level of the groundwater at a remote location. Therefore, it takes more manpower and time than necessary to determine the groundwater condition. There is a problem in that it is not easy to maintain the groundwater as there is a limit to respond quickly.

The present invention has been made to solve the above problems, by supplying the necessary electricity by using the solar energy, and to receive the observation data wirelessly from a remote place to observe the groundwater level and state changes quickly and accurately The aim is to provide a wireless groundwater monitoring system using solar energy to improve groundwater maintenance and utilization efficiency.

Wireless groundwater monitoring system using solar energy according to the present invention for realizing the above object is, the groundwater measuring mechanism is inserted into the observation well and measures at least one or more of the water quality, state, and water level of the groundwater; An automatic measurement main box that receives and stores the measurement result wirelessly or by wire from the groundwater measuring instrument, and transmits the stored information; A photovoltaic electricity supplier for converting solar energy into electrical energy and providing the same to the automatic measurement main box; It is characterized in that it comprises a monitoring device for monitoring the water quality, status, level of the groundwater by receiving the wireless transmission information from the automatic measurement main box.

Preferably, the groundwater measuring instrument is at least one of a water level measuring instrument, a conductivity measuring instrument, and a pH measuring instrument.

The automatic measurement main box is a data logger for receiving and recording a measurement result from the groundwater measuring device, a telemeter for wirelessly transmitting the information recorded in the data logger to the monitoring equipment, and electricity from the solar power supply device. When the supply of energy falls below a certain amount is preferably configured to include a preliminary power supply for supplying power to the automatic measurement main box.

The main problem solving means of the present invention as described above, will be described in more detail and clearly through examples such as 'details for the implementation of the invention', or the accompanying 'drawings' to be described below, wherein In addition to the main problem solving means as described above, various problem solving means according to the present invention will be further presented and described.

The wireless groundwater monitoring system using solar energy according to the present invention is configured to supply necessary electricity using solar energy and to receive observation data wirelessly from a remote location, so that the groundwater level and state change in real time can be monitored. Accurate observation provides the effect of increasing groundwater maintenance and utilization efficiency.

1 is a schematic overall configuration diagram showing a wireless groundwater monitoring system using solar energy according to the present invention.
2 is a block diagram showing the configuration of an embodiment of an automatic measurement main box in the present invention.
3 is a block diagram showing a power supply system using a solar cell panel in the present invention.

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

1 is an overall configuration diagram showing a wireless groundwater monitoring system using solar energy according to the present invention, the system of the present invention is inserted into the observation well 10, the groundwater measuring mechanism for measuring the water quality, state, level, etc. of groundwater ( 20), the automatic measurement main box 30 for receiving and storing the measurement result by wire or wirelessly from the groundwater measuring device 20, and transmitting the stored information, and converts solar energy into electrical energy to measure the automatic measurement main box ( Solar power supply device 40 to provide 30, and the monitoring equipment 50 for monitoring the water quality, status, and water level of the ground water by receiving the wireless transmission information from the automatic measurement main box (30) It is preferable.

Such a system of the present invention, by measuring the groundwater level, conductivity, acidity (pH), temperature, etc. periodically at a predetermined time interval, all the measured data values based on the wireless transmission to the remote as well as remote monitoring the remote The equipment 50 is configured to check the observation data such as the water quality, state, and water level of the groundwater to continuously manage the state and fluctuations of the groundwater.

Hereinafter, the main components of the system of the present invention will be described in detail.

First, the groundwater measuring device 20 is inserted into the observation well 10 and directly or indirectly contacted with the groundwater, so that the groundwater level, electrical conductivity, acidity, temperature, and the like can be measured. The measuring device, the pH measuring device, the temperature measuring device, etc. may be integrated or separately provided to observe the condition of the groundwater.

The groundwater measuring device 20 may periodically input the measured data of the groundwater, electric conductivity, acidity (pH), temperature, and the like, into the automatic measurement main box 30. It is configured to be. At this time, the groundwater measuring device 20 is configured to input data into the automatic measurement main box 30 by wire or wirelessly.

Next, referring to FIG. 2, the automatic measurement main box 30 includes a data logger 32 that receives and records a measurement result from the groundwater measuring device 20 described above, and information recorded in the data logger 32. Telemeter 34 for transmitting the radio to the monitoring equipment 50 and the preliminary to supply power to the automatic measurement main box 30 when the supply of electrical energy in the solar power supply device 40 falls below a certain amount. It is preferably composed of a power supply 38.

Here, the data logger 32 is configured to receive observation data by wire or wirelessly with the groundwater measuring device 20 and record the observation result, and the telemeter 34 is information recorded in the data logger 32 as a data communication device. Including several observation data to be transmitted to the monitoring device 50.

Since the data logger 32 and the telemeter 34 are well known, a detailed description thereof will be omitted.

The preliminary power supply unit 38 will be described in detail when the solar power supply device 40 is described below.

In FIG. 2, reference numeral 36 denotes a control unit for controlling the system of the present invention, and 39 may be an alarm system that indicates when the state of the groundwater is out of the normal reference value. The alarm system is not a necessary configuration and can be omitted if necessary.

On the other hand, the automatic measurement main box 30 may be provided with a measuring instrument control panel for operating and managing the groundwater measuring mechanism 20. Along with this, an apparatus for notifying a measurement state may be provided with an apparatus and an operation management apparatus for operating and managing the system of the present invention.

Next, referring to FIG. 3, the photovoltaic electricity supply device 40 may include a solar cell module 42, a converter 44, a storage battery 46, a measuring device 48, and a control unit 36. have.

Here, the photovoltaic power supply device 40 is a device that collects solar energy using a solar panel, that is, a solar cell module 42, which is commonly used, and converts the solar energy into electrical energy.

The converter 44 converts the DC power generated from the solar cell module 42 into AC power.

The storage battery 46 stores AC power converted by the converter 44.

The measuring unit 48 measures the amount of charge of the power stored in the battery 46 in real time.

The controller 36 supplies the power of the battery 46 to the automatic measurement main box 30 when the measured value measured by the measuring instrument 48 exceeds a preset value set in advance (if the charge amount is sufficient). If the value is less than the set value (for example, when the amount of charge is insufficient because the solar power generation is not made smoothly due to cloudy weather, etc.) to control the power supply to supply the power to the automatic measurement main box 30 in the preliminary power supply (38). It is desirable to be able to be configured.

In this case, the preliminary power supply unit 38 may be a commercial power source or a separate battery.

On the other hand, the storage battery 46, the measuring device 48 and the like is not necessarily a configuration, in this case, the control unit compares in real time with a preset value set in advance the output voltage from the solar cell module 42, solar cells If it is determined that the output voltage of the module 42 exceeds the set value, the AC power passing through the converter 44 is provided to the auto-measuring main box 30. On the contrary, if the output voltage of the solar cell module 42 is less than or equal to the set value, it is reserved. The power supply unit 38 provides the automatic measurement main box 30. Of course, this control unit 36 may include a comparator and a switch for operating this way.

In addition, the groundwater measuring device 20 is preferably configured to supply electrical energy required by the photovoltaic power supply device 40 or the preliminary power supply unit 38.

Next, the monitoring device 50 is a device for receiving information transmitted by the radio meter 34 of the automatic measurement main box 30 to display the groundwater measurement data to the manager.

Such monitoring equipment 50 preferably includes a data receiver, a data storage unit, a data control unit, a data display unit, and the like.

In addition, the monitoring equipment 50 may be configured to wirelessly control all the control mechanisms of the auto-measuring main box 30 to operate and manage the system of the present invention.

As described above, the technical ideas described in the embodiments of the present invention can be performed independently of each other, and can be implemented in combination with each other. While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art. It is possible. Accordingly, the technical scope of the present invention should be determined by the appended claims.

Claims (3)

A groundwater measuring device inserted into the observation well and measuring at least one of water quality, state and level of the groundwater;
An automatic measurement main box configured to receive and store measurement results by wire or wirelessly from the groundwater measuring instrument and to transmit stored information;
A photovoltaic electricity supply device converting solar energy into electrical energy and providing the same to the automatic measurement main box;
Wireless groundwater monitoring system using solar energy, characterized in that it comprises a monitoring device for monitoring the water quality, status, level of the groundwater by receiving the radio transmission information from the automatic measurement main box.
The method according to claim 1,
The groundwater measuring instrument is a wireless groundwater monitoring system using solar energy, characterized in that at least any one or more of a water level measuring device, conductivity measuring device, pH measuring device.
The method according to claim 1,
The automatic measurement main box is a data logger for receiving and recording the measurement result from the groundwater measuring device, a telemeter for wirelessly transmitting the information recorded in the data logger to the monitoring equipment, and electricity from the solar power supply device. Wireless groundwater monitoring system using solar energy, characterized in that it comprises a reserve power supply for supplying power to the automatic measurement main box when the supply of energy falls below a certain amount.

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