JP2016220681A - Water level management system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a management system that saves labor for management of water in rice paddies or the like, and can adjust a water level of rice paddies from a remote place.SOLUTION: A management system performs: a process of installing a feed-water sluice gate 1a and a discharge-water sluice gate 1b and a water level measurement indicator to a farm field, and imaging the farm field and the water level measurement indicator from a drone 27 flying on a predetermined airway; a process of transmitting captured images from the drone; a process of analyzing transmitted images to calculate a water level; and a process of comparing a predetermined reference water level and water level information which is transmitted from the drone and analyzed, and transmitting an opening/closing instruction to the feed-water sluice gate or the discharge-water sluice gate having a wireless module.SELECTED DRAWING: Figure 9

Description

   The present invention acquires various environmental information by a sensor or an unmanned air vehicle equipped with a communication device, adjusts the water gate based on the information, adjusts the water level of the paddy field, and saves management of water such as paddy fields. Regarding management system.

  In recent years, with the aging of farmers and the decrease in the farming population, farm management has become larger and management cultivated land has become larger. Therefore, attempts have been made to use information communication technology using telecommunication lines such as the Internet for agricultural management. According to Patent Document 1, a data collection device that collects environmental information is installed at a remote location, and the environmental information collected by the data collection device is aggregated via a telecommunication line and managed centrally, The use of information communication technology makes it possible to view the environmental information collected by the collection device at a home terminal.

Further, according to the data processing apparatus of Patent Document 2, an image of a water level plate with a scale installed in a paddy field is imaged by a camera unit, and image data of the image imaged by the camera unit is externally used as water level data. It can be transmitted to the center server or the farmer's terminal, which is a terminal, and can be viewed on the farmer's terminal.

Furthermore, according to the paddy field water level adjusting device of Patent Document 3, when the paddy field water level setting signal is transmitted from the transmitter and received from the transmitter, the signal is received by the receiver, and the controller sets the water level signal. It is possible to adjust the water level by rotating the motor, changing the height of the overflow port.

JP2007-199368 JP2009-236638 JP-A-11-113431

  However, in the invention according to Patent Document 1, since it is necessary to go to a place where the sluice is located for water level management (also referred to as deep water management) of paddy fields, it has a large management cultivated land. This is a heavy burden on producers (hereinafter sometimes referred to simply as “producers”, but “producers include producers with management cultivated land other than this scale”). Further, in the data collection device of the invention according to Patent Document 2, since the range that can be photographed by the camera unit is limited, the producer needs a data collection device to cover all the paddy fields managed by the producer. , It will be a big cost burden. Furthermore, in the paddy field water level adjusting device according to Patent Document 3, since the receiving unit, the control unit, the battery, the motor, and the drive mechanism unit are integrally stored in the control box, when any one fails. Difficult to take a quick response.

  In general, the risk of paddy rice cultivation is that water is drained and the paddy is dried up due to straw or mole. It is necessary to monitor paddy fields in order to grasp this situation and resolve it immediately, but it is not easy for the producer. Further, there is a desire to supply water to each field at a predetermined time, but it is difficult for a producer to supply water to each field at the same time.

  In view of the above problems in the prior art, an object of the present invention is to provide a water level information management system that can save labor in sluice management in each field and manage water that is optimal for each field. is there.

  Another object of the present invention is to provide a sluice that can be used for the water level information management system and can be easily maintained by anyone.

  The water level management system of the present invention is a process of installing a water supply sluice 1a, a drainage sluice 1b, and a water level measurement index 5 in a field and photographing the field or the water level measurement index 5 from an unmanned air vehicle 13 flying in a predetermined airway. And a step of transmitting a photographed image from an unmanned air vehicle, a step of calculating a water level by analyzing the transmitted image, and a water level information transmitted and analyzed from an unmanned air vehicle Then, an opening / closing instruction is transmitted to the water supply sluice 1a or the drainage sluice 1b having the wireless module.

  Furthermore, the water level management system of the present invention includes a step of installing a water supply sluice 1a, a drainage sluice 1b, and a sensor 10 in a farm field, and transmitting environmental information from the sensor 10 via a communication device, and transmitted environmental information. The water level is calculated by analyzing the water level and the specified reference water level is compared with the analyzed water level information transmitted from the sensor, and an opening / closing instruction is transmitted to the water supply sluice gate or drainage sluice gate having a wireless module. It is characterized by that.

  The sluice according to the present invention includes an adjustment attachment 3 installed at a water inlet, a mechanism unit 2, a communication unit 5, a control unit 6, a motor 4, and a power source 7, and at least the mechanism unit 2 and the power source 7 are respectively provided. It is a single unit.

  According to the present invention, a sensor installed in each field, a sensor installed in a sluice, or an unmanned air vehicle acquires environmental information related to the water level, etc., transmits the information on the cloud, and automatically opens / closes the paddy field. Since it can be performed by the information terminal of the producer, even a producer having a large management cultivated land does not need to look around all the paddy fields, and a reduction in labor can be expected. Moreover, since environmental information is preserve | saved in the application on a cloud, the producer can obtain easily the information regarding the paddy field in the season, and can also analyze these, yield, etc.

  Moreover, according to this invention, since a sluice can be adjusted with a producer side terminal all at once in predetermined time, water can be supplied simultaneously. In addition, environment information can be transmitted to the terminal every predetermined time, and an opening / closing instruction can be directly given from the terminal to the sluice gate, so that an unpredictable change in the paddy field can be dealt with.

  Furthermore, according to the present invention, since the units constituting the sluice are separate units, for example, when a failure occurs in the battery, only the battery unit needs to be replaced, and anyone can easily perform maintenance. Can be implemented.

FIG. 1 is an overall view of a sluice 1 used in a water level information management system according to an embodiment of the present invention. FIG. 2 is another embodiment of the sluice used in the water level information management system according to the embodiment of the present invention. FIG. 3 is an embodiment of a mechanism unit used in the water level information management system according to the embodiment of the present invention. 4 (a) and 4 (b) are cross-sectional views in which a sluice used in the water level information management system according to the embodiment of the present invention is installed. FIG. 5 is an overall view of the water level measurement index 5 taken by the unmanned air vehicle 13 used in the water level information management system according to the embodiment of the present invention. FIG. 6 is an overall view of the sensor 10 used in the water level information management system according to the embodiment of the present invention. FIG. 7 shows a case where the sluice gate 1 used in the water level information system according to the embodiment of the present invention is installed in each paddy field (not shown), and an open / close instruction is sent from the application on the cloud and the producer side terminal to the sluice gate. It is a block diagram. FIG. 8 is a cross-sectional view of the water level information management system according to the embodiment of the present invention when an unmanned air vehicle is used. FIG. 9 is another cross-sectional view when the unmanned air vehicle of the water level information management system according to the embodiment of the present invention is used. FIG. 10 is another conceptual diagram when the unmanned air vehicle of the water level information management system according to the embodiment of the present invention is used. FIG. 11 shows sensors used in the water level information system according to the embodiment of the present invention installed in each paddy field (not shown), transmitted to a gateway equipped with a solar system, and transmitted from the gateway to an application on the cloud. It is a block diagram. FIG. 12 is a conceptual diagram when the sensor of the water level information management system according to the embodiment of the present invention is used. FIG. 13 is a flowchart when the unmanned air vehicle of the water level information management system according to the embodiment of the present invention is used. FIG. 14 is a flowchart of another implementation when an unmanned air vehicle of the water level information management system according to the embodiment of the present invention is used. FIG. 15 is a flowchart when the sensor of the water level information management system according to the embodiment of the present invention is used. FIG. 16 is a flowchart in the case of using the sensor installed in the sluice of the water level information management system according to the embodiment of the present invention.

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

  FIG. 1 is a schematic view of a sluice 1 used in the present invention. The main sluice 1 is a semi-automatic control sluice equipped with a wireless module, a control device, and a dry cell.

  The water supply sluice according to the present invention will be described in more detail with reference to FIG. The attachment 3 for adjustment is used in order to respond to the size of the water mouth when the mechanism portion is installed in the water mouth because the width and length of the water mouth vary depending on each field. As the power source 7 of the motor 4, natural energy such as a dry battery, a solar battery, wind power, hydraulic power, geothermal heat, or the like can be used. The communication unit 5 can use an electric communication line such as a 3G line, and performs communication with an application on the cloud described later. The control unit 6 transmits a command from the communication unit 5 to the motor 4.

The form of the mechanism will be described with reference to FIG. First, in the first form of the mechanism part (a), a water vent is projected from the lower part of the mechanism part 2, and a cylindrical hose 10 having a substantially equal diameter is extended to the vent. A wire 9 is connected to the tip of the hose 10 from a rigid rod 8. The upper figure (a) shows a state where water is supplied to the paddy field. When the water supply is stopped, the wire 9 is wound up by the motor 4 and the water supply to the paddy field is stopped.
Further, the second form (b) of the mechanism part will be described. A water vent projects from the lower portion of the mechanism portion 2, and a cylinder 13 having substantially the same diameter extends from the vent. A wire 12 is wound at a substantially middle position of the cylinder 13. When stopping the water supply, the wire 12 is squeezed to stop the water supply to the paddy field. The cylinder 13 according to both the embodiments is preferably made of a material such as a soft polyvinyl chloride resin and can be deformed. .
Furthermore, the third form (c) of the mechanism part will be described. At the lower part of the mechanism part 2, a water vent is protruded, and a rigid rod 14 that moves in the vertical direction and a fixed rigid rod 15 are installed.
The rigid rod 14 is attached with a hollow rod and a plate installed thereon. The rigid rod 14 is moved up and down by the motor 4 to supply and drain water. The material of the plate is not particularly limited, but stainless steel or the like may be used in consideration of durability and the like.

  Although not shown, a photographing device such as a camera can be attached as a separate unit. With such a photographing device, it is possible to photograph the water level and grasp the real-time situation. In addition, a unit for measuring various test papers can be installed, and measurement results such as water level and pH can be sent. Furthermore, an environmental information measurement sensor can be attached to acquire various environmental information. Environmental information acquired by various sensors includes temperature and humidity, ground temperature, underground moisture, pH, electrical conductivity, dissolved oxygen, turbidity, solar radiation, carbon dioxide gas, and the like. Various kinds of desired environmental information can be acquired by combining one or more of these.

The temperature / humidity sensor that measures temperature / humidity is a sensor that detects temperature and humidity, such as a platinum resistance thermometer (temperature) and a capacitive polymer type (humidity). Detect temperature and humidity. The ground temperature sensor that measures the ground temperature is a sensor that detects the soil temperature in the paddy field. Moreover, the underground moisture sensor which measures underground moisture is a sensor which detects the soil moisture in a paddy field, for example, an electrical resistance type sensor can be used. A pH sensor that measures pH is a sensor that detects a hydrogen ion concentration in a paddy field. An electrical conductivity sensor that measures electrical conductivity is a sensor that detects the tendency of fertilizer content or agricultural chemicals present in paddy soil using electrical conductivity. The electrical conductivity sensor can also measure various ions (F ⁻ , Cl ⁻ , NO ³⁻ , Ca ²⁺ , K ⁺ , NH ^4+, etc.). The solar radiation amount sensor for measuring the solar radiation amount is a sensor for detecting the total solar radiation amount on the ground surface, and a thermocouple type or the like can be used. The carbon dioxide sensor that measures carbon dioxide is a sensor that detects the CO ² concentration, and a solid polymer type or the like can be used.

4 (a) and 4 (b) are views showing a state in which a sluice is installed in a paddy field. A water supply sluice 1 (a) and a drainage sluice 1 (b) provided with a water amount adjusting plate 17 are installed in a paddle separating a paddy field and a water channel. The power of the water amount adjusting plate 17 can be non-power such as a spring, and a solar cell or the like can also be used.

FIG. 5 shows a water level measurement index 20 made up of a ball 19 placed in a quadrangular pyramid 18 read by an unmanned air vehicle (not shown). This is installed in a paddy field, and an unmanned aerial vehicle shoots the area of the ball in contact with the water surface and obtains water level information by performing image processing. The unmanned air vehicle refers to an air vehicle that moves by remote control or wireless control, and an example is a drone.

  FIG. 6 shows a sensor unit according to the present invention. The installation member 21 includes a measurement unit 23 having a mobile communication function 22 (powered by a dry cell or the like (not shown)) or a sensor unit (various sensors such as an ultrasonic sensor and a temperature sensor). (Not shown)). Various environmental information can be acquired by the sensor 24. Here, the sensor includes a temperature / humidity sensor, a ground temperature sensor, a ground moisture sensor, a pH, an electrical conductivity sensor, a dissolved oxygen sensor, a turbidity sensor, a solar radiation amount sensor, or a carbon dioxide gas sensor. Alternatively, two or more types can be combined to obtain various desired environmental information. In addition, the thing similar to the sensor mentioned above can be used.

FIG. 7 is a schematic diagram in which an opening / closing instruction is transmitted from the application 25 on the cloud to the sluice gate 1. In addition, the water level information system according to the present invention can transmit an opening / closing instruction to the sluice gate 1 from the producer side terminal 26 without using the application 25 on the cloud. Here, the producer-side terminal refers to various information processing terminals such as a smartphone, a tablet, or a personal computer.
Thus, by being able to transmit the opening / closing instruction directly from the producer side terminal to the sluice, it becomes possible to perform the opening / closing operation of the sluice without having to go to each field when suddenly the opening / closing operation of the sluice is required.

The application 25 on the cloud outputs a control command to the control unit of the sluice gate of the paddy field so that the value of the water level of the paddy field becomes a predetermined value. The application 25 on the cloud calculates the water level of the paddy field by analyzing the image of the paddy field captured by the unmanned air vehicle or the sensor value. The calculated water level value of the paddy field is compared with a predetermined reference water level that is set in advance. A control command to increase the opening of the sluice is output. On the other hand, if the value of the water level of the paddy field exceeds a predetermined reference water level, a control command for increasing the opening degree of the sluice is output to the drain side sluice 1a.
Here, the predetermined reference water level refers to a target distance from the ground of the field to the surface of the water. The predetermined reference water level is set based on the cultivar of rice to be cultivated, the growth process of rice, the soil, climate, meteorological conditions, topography of each field, height difference, shape, water temperature or various environmental information, etc. It is determined from an empirical or statistical viewpoint with comprehensive consideration.
As an example, the predetermined reference water level at the time of about two months after rice planting is generally about 10 cm to 15 cm, although it depends on the varieties of rice to be cultivated.
The application 25 on the cloud also has a function of storing environment information collected from various sensors. For example, information such as time and date when the environment information is acquired is stored in association with the environment information.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings.

(First embodiment)
FIG. 8 is a first embodiment of the water level information management system when the unmanned air vehicle 27 is used. This will be described in detail with reference to FIG. As shown in FIG. 8, a water supply sluice 1a, a drainage sluice 1b, and a water level measurement index 20 are installed in each field. The four or five fields or the water level measurement index 20 are photographed by flying with the unmanned air vehicle 27 in which an air route is set in advance. In this case, the time required for photographing is about 15 to 20 minutes. The unmanned air vehicle 27 that has returned to the base (not shown) transmits the image, calculates the water level from the image analysis software, and stores it in the application 25 on the cloud. The preset water level is compared with the water level information transmitted and analyzed from the unmanned air vehicle, and an open / close instruction is sent from the application 25 on the cloud to the water supply sluice 1a having a wireless module or to the drainage sluice 1b. Send. Each of the sluices 1 opens and closes when receiving a signal. An opening / closing instruction can also be transmitted from the producer-side terminal 26 to the sluice gate 1.

(Second Embodiment)
FIG. 9 shows a second embodiment of the water level information management system when the unmanned air vehicle 27 is used. This will be described in detail with reference to FIG. As shown in FIG. 6, a water supply sluice 1a and a drainage sluice 1b are installed in each field. Each field is photographed by flying with an unmanned air vehicle 27 having an air route set in advance. In this case, the time required for photographing is about 15 to 20 minutes. The unmanned air vehicle 27 that has returned to the base (not shown) transmits an image, creates three-dimensional data from the image analysis software, calculates the height difference of the field and / or the chlorophyll of the crop in addition to the water level information. These pieces of information are stored in the application 25 on the cloud. Compares the water level set based on the various information in advance with the various information transmitted and analyzed from the unmanned air vehicle, and gives instructions to open and close to the water supply sluice 1a having the information communication device or to the drainage sluice 1b A signal is transmitted from the application 25 on the cloud. Each of the sluices 1 opens and closes when receiving a signal. Moreover, the application 25 on the cloud can be referred to from the producer-side terminal 26 and an opening / closing instruction can be transmitted to the sluice gate 1.

  One method for calculating the height difference of the field from the image analysis software is as follows. The photo is taken with a lap on the flight course. The camera position (X, Y, Z, Yaw, Pitch, Roll) is estimated by extracting the feature points of each photo and associating the photos by image analysis, and points with 3D coordinates (point cloud) Can also be obtained in large quantities. By analyzing these, orthophoto, point cloud data, DSM, 3D model, etc. can be obtained as output data.

  As the first effect of calculating the height difference of the field, the lodging of rice can be prevented. Specifically, it is necessary to deepen the paddy field to prevent the rice from falling down due to sudden changes in weather conditions such as when a typhoon or developed low pressure approaches. Therefore, the height difference of the field is analyzed in advance by an unmanned airplane, and a sensor is installed at a low part of each field. Subsequently, the water level of the said location is measured. Then, compared to a reference water level set in advance to prevent rice lodging, the sluice gate is instructed to open and close, and the water level is set to the reference water level, thereby preventing rice lodging. In addition, measures for leveling the field can be taken by measuring the height difference of the field during periods when rice is not growing.

  As a second effect of calculating the height difference of the field, it is possible to appropriately spray and manage the agricultural chemical. Since the sprayed pesticides stay in a low part of the field for a long time, the microorganisms in the soil are killed. Moreover, if the height difference is large, the sprayed pesticide simply flows out, and the effect of the pesticide cannot be obtained. Furthermore, if the pesticides are not adequately sprayed, it will adversely affect the growth of rice cultivation and will lay down the rice at harvest time. Therefore, sensors are installed at high and low locations in the field, and if the pesticides are determined to be accumulated from the measurement results at these locations, the water level is adjusted by opening and closing the sluice gates. It is possible to adjust to an appropriate amount by rejecting. By performing this for each farmer's field, the water can be managed optimally.

  By analyzing the leaf color of the crops in the field and calculating chlorophyll, it is possible to grasp the state at the time of analysis in the rice growth process. That is, by measuring the chlorophyll of rice, it is possible to determine whether or not the amount of water and / or fertilizer in each field is sufficient for the growth of rice and take measures. As an example, a water level can be adjusted so that a predetermined reference value is obtained by installing a sensor afterwards in a location where the amount of water is insufficient. Therefore, it is possible to manage the optimum water for each field while directly considering the growth state of the rice in each field, not just information such as the water level and temperature of the paddy field.

(Third embodiment)
FIG. 10 shows a third embodiment of the water level information management system when the unmanned air vehicle 27 is used. This will be described in detail with reference to FIG. In this embodiment, an unmanned air vehicle 27 equipped with a communication device (not shown) or a sensor (not shown) is used. A water supply sluice 1a, a drainage sluice 1b, and a water level measurement index 20 are installed in each field. The water level measurement index 20 is photographed by the flight of the unmanned air vehicle 27 having an air route set in advance. Water level information is acquired by an on-board sensor (not shown), analyzed from a preset water level setting value and the obtained information, and supplied to a water supply sluice gate 1a or a drainage sluice gate 1b having a wireless module. An opening / closing instruction is given via a communication device (not shown). Each of the sluices 1 opens and closes when receiving a signal. An opening / closing instruction can also be transmitted from the producer-side terminal 26 to the sluice gate 1.

(Fourth embodiment)
FIG. 11 shows a fourth embodiment of the water level information management system when the sensor 24 shown in FIG. 6 is used. This will be described in detail with reference to FIG. A sensor 24 is installed for each field (not shown), and a gateway 28 having one solar panel battery is installed for every 10 fields. The sensor 24 installed for each field measures the water level, water temperature, temperature, humidity, etc. of the paddy field every predetermined time, and these data are wirelessly applied via the gateway 28 equipped with a solar panel on the cloud. 25. The preset water level is compared with the analyzed water level information transmitted from the sensor 10, and an open / close instruction is transmitted from the application on the cloud to the water supply sluice 1a or the drainage sluice 1b having a wireless module. Each of the sluices 1 opens and closes when receiving a signal. An opening / closing instruction can also be transmitted from the producer-side terminal 26 to the sluice gate 1.

(Fifth embodiment)
FIG. 12 shows a fifth embodiment of the water level information management system when the sensor 24 shown in FIG. 4 is used. This will be described in detail with reference to FIG. The sensor 24 is installed for each field, and the sluice 1 is installed for each field. The sensor 24 installed for each farm measures various environmental information such as the water level, water temperature, temperature, and humidity of the paddy field at a predetermined time, and stores these data in the application 25 on the cloud by the information communication means. The water level set in advance corresponding to various environmental information etc. is compared with various environmental information such as the water level transmitted from the sensor 10 and analyzed, and a water supply sluice (not shown) having information communication means or for drainage An open / close instruction is transmitted to the sluice gate (not shown) from the application 26 on the cloud. Each sluice gate opens and closes when it receives a signal. Further, an opening / closing instruction can be transmitted from the producer side terminal 12 to the water supply sluice gate or the drainage sluice gate.

(Sixth embodiment)
FIG. 12 shows a sixth embodiment of the water level information management system when the water gate 1 is used. This will be described in detail with reference to FIG. A sluice 1 is installed for each field. Sensors (not shown) installed in each sluice measure the water level, water temperature, temperature, humidity, etc. of the paddy field at predetermined time intervals, and store these data in the application 25 on the cloud by various information communication means. A predetermined reference water level set corresponding to various environmental information and the like is compared with various environmental information such as the water level transmitted from the sensor and analyzed, and a water supply sluice 1a or a drainage sluice 1b having various communication functions. An open / close instruction is transmitted from the application 25 on the cloud. Each of the sluices 1 opens and closes when receiving a signal. Moreover, the said data on a cloud can be transmitted / received from the producer side terminal 26, and the opening / closing instruction | indication can also be transmitted to the water gate 1a for water supply or the gate 1b for drainage.

The present invention can greatly reduce the labor required for water level management in paddy fields and the like, and can easily perform water level management by giving an opening / closing instruction to a sluice having a wireless module.

Claims (9)

A water supply sluice, a drainage sluice, and a water level measurement index are installed in the field, and the field or water level measurement index is imaged from an unmanned air vehicle flying in a predetermined air route, and the captured image is transmitted from the unmanned air vehicle. Comparing the process, the step of calculating the water level by analyzing the transmitted image, and the water level information transmitted from the unmanned air vehicle and analyzed, and comparing the predetermined reference water level and the water supply sluice or drainage with a wireless module A water level management system characterized by transmitting an opening / closing instruction to a sluice gate Installing a water supply sluice gate, drainage sluice gate and sensor in the field, acquiring environmental information from the sensor, transmitting acquired environmental information through communication equipment, and analyzing the transmitted environmental information Comparing the predetermined reference water level with the water level information transmitted from the sensor and analyzed, and sending an opening / closing instruction to the water supply sluice gate or drainage sluice gate having a wireless module. Features water level management system The unmanned air vehicle is equipped with a communication device and a sensor, acquires water level information by the mounted sensor, calculates a water level by analyzing the acquired water level information, and calculates the calculated water level and a predetermined reference water level. 2. The water level management system according to claim 1, wherein an opening / closing instruction is issued via a communication device mounted on a water supply sluice gate or a drainage sluice gate having a wireless module based on a result of comparing Installing a water supply sluice gate and a drainage sluice on the farm field, photographing the farm field from an unmanned air vehicle flying on a predetermined air route, transmitting the photographed image from the unmanned air vehicle, and analyzing the transmitted image Water supply with an electric communication line by comparing the step of calculating the height difference of the field and the predetermined reference water level set based on the height difference of the field with the water level information transmitted from the unmanned air vehicle and analyzed. A water level management system characterized by transmitting an opening / closing instruction to a sluice gate or a drainage sluice gate Installing a water supply sluice gate and a drainage sluice on the farm field, photographing the farm field from an unmanned air vehicle flying on a predetermined air route, transmitting the photographed image from the unmanned air vehicle, and analyzing the transmitted image The chlorophyll of rice is calculated, and a predetermined reference water level set from the chlorophyll of rice is compared with the water level information transmitted and analyzed from the unmanned air vehicle. A water level management system characterized by transmitting an opening / closing instruction to a sluice gate Installing a water supply sluice gate, drainage sluice gate and sensor in the field, acquiring environmental information from the sensor, transmitting acquired environmental information through communication equipment, and analyzing the transmitted environmental information The water level is calculated and the specified reference water level set from the environmental information is compared with the water level information transmitted and analyzed from the sensor. A water level management system characterized by transmitting an opening / closing instruction Installing a water supply sluice gate and a drainage sluice gate equipped with a sensor in the field, acquiring environmental information from the sensor, transmitting the acquired environmental information through a communication device, and transmitting the environmental information Analyzing and calculating the water level and comparing the specified reference water level set from the environmental information with the environmental information transmitted from the sensor and analyzed, and for the water supply sluice gate or drainage sluice gate that has a telecommunication line A water level management system characterized by The environmental information is any one or more of temperature and humidity, earth temperature, underground moisture, pH, electrical conductivity, dissolved oxygen, turbidity, solar radiation, and carbon dioxide gas. The water level management system as described in any one of thru | or 7 The water supply sluice according to any one of claims 1 to 8 includes an adjustment attachment, a mechanism unit, a communication unit, a control unit, a motor, and a power source. At least the mechanism unit, the power source, and The water level management system according to any one of claims 1 to 8, wherein each is a single unit.

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