JP4697452B2 - Wide-area distributed water distribution management system - Google Patents

Description

  The present invention relates to a wide-area distributed water distribution management system for distributing water from a river to a plurality of regions.

Conventionally, agricultural water is used by taking water from a river through a water intake gate and distributing the water to each farmer. That is, the water taken through the water intake gate is divided through a water divider, and the water thus distributed is distributed to each farmhouse.
As a system using such agricultural water, various wide-area distributed water distribution management systems have been proposed.

As these wide-area distributed water distribution management systems, water distribution valves are controlled by electric power based on information input by an IC card, and water can be supplied by a user operating an electric valve or a manual valve. It has been proposed (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 5-174036

However, the wide-area distributed water distribution management system described in Patent Document 1 as described above has a problem that a commercial power source cannot be obtained and a distribution valve cannot be controlled in a place where a distribution line cannot be installed. .
Also, in locations where distribution lines cannot be installed, it is difficult to manage the amount of use for each user because the amount of water used for each user cannot be transmitted and the water distribution valve cannot be controlled according to the amount of use. Become.
Furthermore, since it is necessary for the user to perform water supply by opening and closing the manual valve, water supply work becomes troublesome.

  The present invention has been made in view of such circumstances, and not only can a power supply be obtained stably and reliably even in a place where a commercial power source cannot be obtained, but also allows quick and easy water distribution. It is another object of the present invention to provide a wide-area distributed water distribution management system that can perform management with high accuracy for each user.

In order to solve the above problems, the present invention provides the following means.
A wide-area distributed water distribution management system according to the present invention is a wide-area distributed water distribution management system for distributing water from a river to a plurality of areas, and controls the intake gate provided in the river and the intake gate A gate control unit, a plurality of power supply units each capable of self-supply, a power storage unit that stores electric power from the plurality of power supply units, and supplies the stored electric power to the gate control unit, and water is supplied from the intake gate. A water wheel provided in a distribution channel into which the water flows and rotated by the water, and the gate control unit receives wirelessly transmitted flow rate information indicating a flow rate of water necessary for each of the plurality of regions. When, and a water level gauge for detecting the water level of the river, and, based on the detected water level by flow rate information and said water gauge received by the receiving unit, the water intake gate Controls, the plurality of power supply unit includes a comprising: a waterwheel generator unit for converting the rotational energy generated by rotation of the water wheel power, and solar power generation unit that generates electrical power from solar light energy To do.

In the wide-area distributed water distribution management system according to the present invention, power from a plurality of power supply units is stored by the power storage unit, and this power is supplied to the control unit. Moreover, the flow rate information transmitted by radio is received by the receiving unit, and the intake gate is controlled by the control unit based on the received flow rate information.
Thereby, even if it is a place where a commercial power supply cannot be obtained, electric power can be obtained stably and reliably. In addition, since a plurality of power supply units are provided, at least one of the power supply units can be operated, and power can be generated more reliably.
In addition, since the flow rate information transmitted wirelessly is received and the intake gate is controlled, it is possible not only to perform autonomous control of the intake gate based on this flow rate information, but also to distribute water quickly and reliably. .
Furthermore, the flow rate can be managed based on the flow rate information.

According to the wide-area distributed water distribution management system according to the present invention, power can be generated by the water turbine power generation unit even at night or in bad weather, and solar power can be used even when hydropower is not available. Electric power can be generated by the power generation unit.
Thereby, at least any one among a plurality of power supply parts can be operated reliably, and electric power can be generated stably and reliably.

The wide-area distributed water distribution management system according to the present invention is a wide-area distributed water distribution management system for distributing water from a river to a plurality of areas, the intake gate provided in the river, and the intake gate A gate control unit for controlling the power supply, a plurality of power supply units each capable of being self-supplied, a power storage unit for storing power from the plurality of power supply units, and supplying the stored power to the gate control unit, and the intake gate A water wheel that is provided in a distribution channel into which irrigation water flows and is rotated by the irrigation water, a storage unit that stores flow rate information indicating a flow rate of irrigation water required for each of the plurality of regions, and a transmission unit that wirelessly transmits the flow rate information , wherein the gate control unit includes a receiver for receiving the flow rate information wirelessly transmitted from the transmitting unit, and a water level gauge for detecting the water level of the river, and the receiver Based on the water level detected by the flow rate information and said water gauge received Te, the controls intake gates, said plurality of power supply unit, hydraulic turbine power generation unit that converts the rotational energy generated by rotation of the water wheel to power And a solar power generation unit that generates electric power from solar light energy .

In the wide-area distributed water distribution management system according to the present invention, power from a plurality of power supply units is stored by the power storage unit, and this power is supplied to the control unit. The flow rate information is stored in the storage unit, and the flow rate information is wirelessly transmitted by the transmission unit. The wirelessly transmitted flow rate information is received by the receiving unit, and the intake gate is controlled by the control unit based on the received flow rate information.
Thereby, not only the effect similar to the invention according to claim 1 can be obtained, but also more accurate flow rate management can be performed based on the flow rate information stored in the storage unit.

  According to the present invention, since the power storage unit stores power from a plurality of power supply units that can be self-supplied, it is possible to supply power stably and reliably. In addition, since the flow information transmitted wirelessly is received and the intake gate is controlled based on the received flow information, water can be distributed quickly and easily, and highly accurate management is performed for each user. Can do.

(Embodiment)
Hereinafter, a wide-area distributed water distribution management system in an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 shows a wide-area distributed water distribution management system as an embodiment of the present invention.
The wide-area distributed water distribution management system 1 includes a water intake unit 2 for taking agricultural water from the main water R and a management device 3 for managing the flow rate of each user or territory.

  The intake part 2 is installed for each farmland 1 to n. Since the structure of the water intake unit 2 is the same, only one water intake unit 2 will be described here.

The intake section 2 includes an automatic power supply type intake gate 6 installed at a connection portion between a distribution channel 5 for distributing agricultural water to the farmland 1 and the basic water R. The intake gate 6 is provided so that it can be raised and lowered. And the flow volume of the water which flows in into the water distribution path 5 from the basic water R is adjusted by raising / lowering the intake gate 6.
A water wheel 7 is provided in the water distribution channel 5. The water turbine 7 is rotated by the water flowing through the water distribution channel 5 so that rotational energy can be obtained.

  The water turbine 7 is connected to a generator (power supply unit, water turbine power generation unit) 8. The generator 8 converts rotational energy generated by the rotation of the water turbine 7 into electric power. The power generator 8 is connected to a storage battery (power storage unit) 11 via a power generation controller 13, and the storage battery 11 stores power generated by the power generator 8. The storage battery 11 is connected to a light receiving unit (power source unit, solar power generation unit) 16 via a power generation controller 13. The light receiving unit 16 receives sunlight and converts the light energy into DC power.

Furthermore, the storage battery 11 is connected via a power generation controller 13 to a gate controller (gate control unit) 12 that controls driving of the intake gate 6. The gate controller 12 is connected to a water level meter 17 that detects the water level of the basic water R.
FIG. 2 is a block diagram showing the gate controller 12 for each function.
The gate controller 12 includes a control unit 32 that controls the entire gate controller 12.

  The control unit 32 is connected to the water level gauge 17 through the I / O unit 33 and is connected to the intake gate 6 through the I / O unit 36. The control unit 32 and the I / O unit 36 are connected to the storage battery 11 via the power generation controller 13, and driving power is supplied from the storage battery 11. Further, the control unit 32 is connected to a transmission / reception unit (reception unit) 31 for receiving flow rate information described later, and the transmission / reception unit 31 is connected to the antenna 30.

FIG. 3 is a block diagram showing the management apparatus 3 for each function.
The management device 3 is installed at a central management office or the like separated from the water intake unit 2, and manages the flow rate necessary for the farmland 1 to n.
The management device 3 includes a control unit 22 that manages the entire management device 3. The control unit 22 is connected to the input unit 25. The input unit 25 is for an operator to input the areas of the farmland 1 to n, the type of crop, the weather condition, and the like. And the control part 22 calculates the flow volume information of the water required for each of the farmlands 1-n from the area of these farmlands 1-n, the kind of crop, a weather condition, etc.

  The control unit 22 is connected to the storage unit 26 and stores the calculated flow rate information in the storage unit 26. Further, the control unit 22 is connected to a transmission / reception unit (transmission unit) 21 for transmitting the calculated flow rate information. The transceiver unit 21 is connected to the antenna 20.

Next, the operation of the wide-area distributed water distribution management system 1 in the present embodiment configured as described above will be described.
First, the electric power obtained by the light receiving unit 16 is sent to the storage battery 11 via the power generation controller 13 and stored in the storage battery 11. And the gate controller 12 is driven by the electric power stored in the storage battery 11, and the intake gate 6 is raised and lowered.
Further, when the intake gate 6 is raised or lowered and water flows from the main water R to the water distribution channel 5, the water wheel 7 rotates, and the rotational energy of the water wheel 7 is converted into electric power by the generator 8. Then, the electric power obtained by the generator 8 is stored in the storage battery 11 via the power generation controller 13.

Thus, in the state where electric power is stored in the storage battery 11, the raising and lowering of the intake gate is controlled as follows.
First, at a central management office or the like, an operator operates the input unit of the management device 3 to input, for example, the area of the farmland 1, the type of crop, the weather condition, and the like. Then, the information is input to the control unit 22. Based on the information, the control unit 22 calculates flow rate information using a predetermined calculation formula. And the control part 22 memorize | stores flow volume information in the memory | storage part 26 for every user or a territory. Furthermore, the control part 22 adds the identification information for identifying the farmland 1 to the calculated flow volume information, and makes it the identification flow volume information. And the control part 22 modulates the carrier wave which has a predetermined frequency by the transmission / reception part 21 with an identification flow rate information signal. Then, the control unit 22 transmits the modulated signal via the antenna 20.
The flow rate information stored in the storage unit 26 is displayed on a display device such as a monitor. Further, the flow rate information stored in the storage unit 26 is read, and the flow rate information for each user is collected and analyzed by a personal computer or the like, and used for various flow rate management.

  On the other hand, the control unit 32 of the gate controller 12 receives the transmitted signal (identification flow rate information) via the antenna 30. And the control part 32 demodulates the received signal by the transmission / reception part 31, and reproduces | regenerates an identification flow information signal. This identification flow rate information signal is input to the control unit 32. The control unit 32 extracts the identification information from the input identification flow rate information signal, and determines whether or not it is addressed to itself based on this identification information. If it is determined that it is not addressed to itself, the control unit 32 discards the identification flow rate information and the like. On the other hand, if it is determined that it is for itself, the control unit 32 takes out the flow rate information and inputs a drive signal corresponding to the flow rate information to the drive unit of the intake gate 6 via the I / O unit 36. . Thereby, the intake gate 6 rises or descends, and water flows from the basic water R to the water distribution channel 5. Then, when a predetermined time based on the flow rate information (a time required for the required flow rate to flow through the distribution channel 5) has elapsed, the control unit 32 sends a drive signal to the drive unit of the intake gate 6 via the I / O unit 36. input. Thereby, the intake gate 6 descend | falls or raises, and the inflow to the water distribution path 5 is stopped.

  When the detection result of the water level gauge 17 is input as a detection signal to the control unit 32 via the I / O unit 33, the control unit 32 determines whether the intake gate 6 is taking water according to the water level of the main water R. Adjust the height. Thereby, it adjusts so that the flow volume from main water R to distribution channel 5 may become always constant.

As described above, according to the wide-area distributed water distribution management system 1 according to the present embodiment, since the water turbine 7 and the generator 8 that can be self-supplied, and the light receiving unit 16 and the power generation controller 13 are included, a commercial power source cannot be obtained. Even at a place, power can be obtained stably and reliably. Therefore, automatic operation of the water intake unit 2 can be performed, and labor saving can be achieved.
Further, since the gate controller 12 receives flow rate information wirelessly transmitted from a remote location and controls the drive of the intake gate 6 based on the received flow rate information, it is a place where a signal line cannot be laid. However, it is possible to distribute water to each farmer quickly and reliably. Furthermore, since it is not necessary to drive the water intake gate 6 by an operator's manual operation, manpower can be reduced.
Furthermore, since the flow rate information is stored in the storage unit 26 for each user or territory, it is possible to centrally manage the amount of water used, and to plan the equipment according to each demand.

  In addition, since it has a plurality of power generation units such as a water turbine 7 and a generator 8 that can be self-sufficient, and a light receiving unit 16, one is hydropower generation and the other is solar power generation. One of them can be operated reliably. In the present embodiment, power can be generated by hydroelectric power generation even at night or in bad weather, and power can be generated by solar power generation even when hydropower is not available. .

In the present embodiment, the management device 3 transmits and receives wirelessly using the transmission / reception unit 21 and the antenna 20, but the present invention is not limited to this, and the management device 3 is connected to an external communication device by wire. May be. As a result, the antenna 20 and the like are not required, and the configuration can be simplified.
Moreover, although the control part 22 of the management apparatus 3 calculated flow volume information, it is not restricted to this, An operator may input flow volume information directly.
The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

1 is an overall configuration diagram showing an embodiment of a wide-area distributed water distribution management system according to the present invention. It is a block diagram which shows the gate controller of FIG. 1 for every function. It is a block diagram which shows the management apparatus of FIG. 1 for every function.

Explanation of symbols

1 Wide-area decentralized water distribution management system 6 Intake gate 7 Water turbine (power supply unit, water turbine power generation unit)
8 Generator (power supply unit, turbine generator unit)
11 Storage battery (power storage unit)
12 Gate controller (gate controller)
13 Power Generation Controller 16 Light Receiving Unit (Power Supply Unit, Solar Power Generation Unit)
21 Transmitter / receiver (transmitter)
31 Transceiver (Receiver)

Claims (2)

A wide-area distributed water distribution management system for distributing water from a river to multiple areas,
A water intake gate provided in the river;
A gate control unit for controlling the intake gate;
A plurality of power supply units,
A power storage unit that stores power from the plurality of power supply units and supplies the stored power to the gate control unit;
A water wheel provided in a water distribution channel through which irrigation water flows from the intake gate, and rotated by the irrigation water ,
The gate controller is
A receiving unit that receives wirelessly transmitted flow rate information indicating a flow rate of water required for each of the plurality of regions, and a water level meter that detects a water level of the river , and received by the receiving unit Control the intake gate based on flow rate information and the water level detected by the water level gauge ,
The plurality of power supply units include a water turbine power generation unit that converts rotational energy generated by the rotation of the water turbine into electric power, and a solar power generation unit that generates electric power from solar light energy. Distribution management system. A wide-area distributed water distribution management system for distributing water from a river to multiple areas,
A water intake gate provided in the river;
A gate control unit for controlling the intake gate;
A plurality of power supply units,
A power storage unit that stores power from the plurality of power supply units and supplies the stored power to the gate control unit;
A water wheel provided in a water distribution channel through which water flows from the intake gate, and rotated by the water;
A storage unit for storing flow rate information indicating a flow rate of water required for each of the plurality of regions;
A transmission unit that wirelessly transmits the flow rate information,
The gate controller is
A receiver for receiving the flow rate information wirelessly transmitted from the transmitting unit, and a water level gauge for detecting the water level of the river, and was detected by flow rate information and said water gauge received by the receiving unit level based on, it controls the water intake gate,
The plurality of power supply units include a water turbine power generation unit that converts rotational energy generated by the rotation of the water turbine into electric power, and a solar power generation unit that generates electric power from solar light energy. Distribution management system.

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