KR20140072594A - A greenhouse watering system - Google Patents

Abstract

The present invention relates to a greenhouse watering system comprising: a solar panel generating electricity by converting solar energy into electric energy; an independent electricity converting unit converting electricity produced in the solar panel and outputting; a grid connected electricity converting unit connected with an external system power source, converting electricity supplied from the system power source and outputting; a supplying unit supplying electricity outputted from one of the independent electricity converting unit and the grid connected electricity converting unit; and an irrigation control unit connected to the supply unit and controlling the amount of irrigation depending on soil moisture content in the greenhouse and predetermined irritation time.

Description

A greenhouse watering system

The present invention relates to a greenhouse watering system, and more particularly, to a greenhouse watering system using a solar cell.

Irrigation in agriculture is an important factor in crop productivity. By controlling irrigation, more optimal growth conditions can be created and maintained, increasing crop yields for a given amount of land. The cost of having watering equipment therefor and water for supplying watering equipment. In some parts of the world it is advantageous to use water resources that are available in the most cost effective and possibly conservative manner due to lack of water.

In particular, in the case of plantation sites where fruits and vegetables are grown, the desired cultivation environment conditions should be maintained. However, the operation of the irrigation pump to maintain the soil moisture requires a lot of power consumption.

There are also a large number of agricultural greenhouses that are subject to regional restrictions that do not provide electricity.

KR 2008-0002928 (publication number)

The present invention is intended to replace the power consumed by the irrigation pump with the power using solar power generation. It is also intended to provide an interconnected power system capable of using both the battery power and the electricity supplied from the grid power by additionally providing a separate grid type power conversion device separate from the battery storing the developed power.

The present invention relates to a solar panel for converting solar energy into electric energy to produce electricity; An independent power converter for converting the electricity generated by the solar panel and outputting the converted electricity; A system-connected power converter connected to an external system power source to convert and supply electricity supplied from the system power source; A supply unit for supplying power output from the independent power conversion unit or the grid-connected power conversion unit to the water control unit; And an irrigation control unit connected to the supply unit and controlling the irrigation water quantity according to the amount of soil water inside the greenhouse and a predetermined irrigation water time; And a greenhouse watering system.

According to the present invention, it is possible to use the electricity supplied from the system power supply even if the power of the storage battery is exhausted at a specific time when a large amount of water is needed, and the power that is continuously produced beyond the storage limit of the battery by the grid- It can be supplied to other customers.

FIG. 1 is a block diagram showing a greenhouse watering system using a solar cell according to the present invention.

The present invention relates to a greenhouse watering system, and more particularly, to a solar panel that converts solar energy into electric energy to produce electricity; An independent power converter for converting the electricity generated by the solar panel and outputting the converted electricity; A system-connected power converter connected to an external system power source to convert and supply electricity supplied from the system power source; A supply unit for supplying power output from the independent power conversion unit or the grid-connected power conversion unit to the water control unit; And an irrigation control unit connected to the supply unit and controlling the irrigation water quantity according to the amount of soil water inside the greenhouse and a predetermined irrigation water time; .

The system further comprises a circuit for supplying electricity generated by the solar panel to the independent power conversion unit or the grid-connected power conversion unit, wherein the grid-connected power conversion unit supplies electricity generated by the solar panel to the grid power supply .

In addition, the solar panel may further include a water injection device for cleaning pollutants attached to the solar panel.

The independent power conversion unit according to the present invention includes: a converter for level-converting the AC power generated by the solar panel and outputting the converted AC power to a DC power source; A stand-alone inverter for level-converting and outputting the DC power outputted from the converter to an AC power; And a battery for storing electricity using the electric energy converted by the converter; And a battery voltage monitoring unit connected to the stand-alone inverter and the battery to switch to grid-connected power when the power of the battery is exhausted.

According to another aspect of the present invention, there is provided an irrigation control unit comprising: a signal input unit for measuring a water content of a soil; A control unit for controlling the amount of water according to the water amount of the soil measured by the signal input unit and the irrigation water time set by the user; And an output section which is controlled by the control section; . ≪ / RTI >

Here, the signal input unit may include at least one sensor, and the sensor may be a moisture tension sensor.

Meanwhile, the sensor has one or more sensors selected from the group consisting of a water tension (pF) of 2.1 (-13 kPa), a water tension of pF 2.3 (-20 kPa), 2.5 (-30 kPa) and 2.7 Is used.

The control unit may include a mode selector configured to include a moisture sensor mode, a timer mode, a forced mode, and a stop mode; And a timer unit for controlling the watering start point, the water amount, and the watering time by a mode selected and configured by a daily timer and an operation / break timer.

Particularly, in the moisture sensor mode, it is possible to determine the watering start point by comparing the water tension of the soil and the water tension of the sensor attached to the signal input unit. The timer mode is a mode in which the operation of the output unit Is controlled.

Further, the water control apparatus according to the present invention may further include an irrigation pump that receives a signal from the output unit and operates according to the soil moisture requirement.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

FIG. 1 is a block diagram showing a greenhouse watering system using a solar cell according to the present invention.

Hereinafter, the configuration and functions of the greenhouse watering system using the solar cell according to the present invention will be described in detail with reference to FIG.

As shown in FIG. 1, the greenhouse watering system using a solar cell replaces power consumed by the irrigation pump 520 with electric power using solar power generation. More specifically, the solar panel 100, A grid-connected power conversion unit 300, a supply unit 400, and an irrigation control unit 500.

First, the solar panel 100 according to the present invention converts sunlight energy into electric energy. In order to increase the power generation efficiency, the solar panel 100 accurately grasps the position of the sun, So that the solar panel 100 can maintain an optimal angle of view. In addition, the solar panel 100 can be installed with a skew through a plurality of frames.

The solar panel 100 may further include a water injection device for washing the pollutants attached to the solar panel 100. [

More specifically, the water injection device may be composed of a spray nozzle connected to an end of a water supply hose equipped with a pump and mounted to adjust the spray angle.

The independent power conversion unit 200 converts the electricity generated by the solar panel 100 into electric power for irrigation control and outputs the electricity. More specifically, the independent power conversion unit 200 includes a converter 210, a stand-alone inverter 220, 230, and may further include a battery voltage monitoring unit 240.

In this case, the converter 210 is a device for level-converting the AC power generated by the solar panel 100 and outputting it as a DC power. The stand-alone inverter 220 is a device for converting the DC power output from the converter 210 into AC Means a device for level-converting and outputting power to a power source. In addition, the battery 230 according to the present invention can store electricity using the electric energy converted by the converter 210.

The battery voltage monitoring unit 240 may be a device that is connected to the stand-alone inverter 220 and the storage battery 230 and switches to grid-connected power when the power of the storage battery 230 is exhausted.

Further, the greenhouse watering system using the solar cell according to the present invention further includes a grid-connected power conversion unit 300, which is connected to an external grid power supply, converts electricity supplied from the grid power supply into electric power for irrigation control, . And a supply unit 400 for supplying the water control apparatus control power output from the independent power conversion apparatus or the grid-connected power conversion apparatus to the water control unit 500.

More specifically, the electricity supplied from the grid power source can be used even if the power of the battery 230 is exhausted at a specific time when a large amount of water is needed due to the grid-connected power converter 300. Also, the grid-connected power converter 300 can supply power to the other consumers over the storage limit of the storage battery 230.

(600) (two connection boxes) for supplying electricity generated by the solar panel (100) to the independent power conversion unit (200) or the grid connection type power conversion unit (300) The grid-connected power conversion apparatus supplies electricity generated by the solar panel (100) to the grid power.

Meanwhile, the water control unit 500 according to the present invention includes a signal input unit, a control unit, and an output unit 510.

The signal input unit may include at least one sensor for measuring the moisture content of the soil.

The sensor used herein is a moisture tension sensor having a water tension of 2.1 (-13 kPa), a water tension of 2.3 (-20 kPa), a water tension of 2.5 (-30 kPa) and a water tension of 2.7 (-50 kPa) may be used.

For example, in an orchard cultivating melon, a moisture tension soil moisture tension sensor is used, and according to each growth stage, a suitable sensor can be used to control the irrigation water to prevent the heat of the melon and improve the quality.

The control unit according to the present invention controls the amount of water according to the water amount of the soil measured by the signal input unit and the irrigation water time set by the user, and includes a moisture sensor mode, a timer mode, a forced mode, ; And a timer unit for controlling the watering start point, the water flow rate, and the watering time by the mode selected and configured by the daily timer and the operation / break timer.

Particularly, in the moisture sensor mode, the water tension may be compared with the water tension of the sensor attached to the signal input unit to determine the water starting point.

Also, the timer mode may control the operation of the output unit 510 for the time input to the daily timer.

More specifically, the water sensor mode performs watering based on the water tension sensor attached to the signal input unit, and starts watering when the water content of the soil is detected below the water tension sensor.

Then, the irrigation is performed during the operation time set by the operation / relaxation timer after the start of the irrigation, and the irrigation is stopped for the resting time described in the operation / relaxation timer after the operation time has elapsed.

Accordingly, the user adjusts the operation time of the output unit 510 such as the pump and the solenoid valve by adjusting the watering time through the operation / break timer, so that unnecessary irrigation is performed for the time measured by the water moisture tension sensor of the soil .

100: Solar panel
200: Independent power conversion unit
210: converter 220: stand-alone inverter
230: storage battery 240: battery voltage monitoring unit
300: grid-connected power conversion unit
400:
500: Irrigation control unit
510: output section 520: irrigation pump
600: circuit

Claims (12)

Solar panels that convert electricity from solar energy into electric energy to produce electricity;
An independent power converter for converting the electricity generated by the solar panel and outputting the converted electricity;
A system-connected power converter connected to an external system power source to convert and supply electricity supplied from the system power source;
A power supply unit for supplying power output from the independent power conversion unit or the grid-connected power conversion unit; And
An irrigation control unit connected to the supply unit and controlling the amount of water according to the amount of soil water in the greenhouse and a predetermined irrigation time; A greenhouse watering system. The method according to claim 1,
Further comprising a circuit for supplying electricity generated by the solar panel to the independent power conversion unit or the grid-connected power conversion unit,
Wherein the grid-connected power converter supplies electricity generated by the solar panel to the grid power. The method according to claim 1,
Wherein the independent power converter converts a level of the AC power generated by the solar panel into a DC power;
A stand-alone inverter for level-converting and outputting the DC power outputted from the converter to an AC power; And
A battery for storing electricity using electric energy converted by the converter; A greenhouse watering system. The method of claim 3,
Further comprising a battery voltage monitoring unit connected to the stand-alone inverter and the battery to switch to grid-connected power when the power of the battery is exhausted. The method according to claim 1,
The irrigation control unit includes: a signal input unit for measuring a moisture content of the soil;
A control unit for controlling the amount of water according to the water content of the soil measured by the signal input unit and the predetermined watering time; And
An output unit controlled by the control unit; A greenhouse watering system. 6. The method of claim 5,
The signal input unit
Wherein the at least one sensor comprises at least one sensor. The method according to claim 6,
Wherein the sensor is a water tension sensor. 8. The method of claim 7,
The sensor uses one or more sensors selected from the group consisting of a water tension (pF) of 2.1 (-13 kPa), a water tension of pF 2.3 (-20 kPa), 2.5 (-30 kPa) and 2.7 A greenhouse watering system. 6. The method of claim 5,
The control unit may include a mode selector configured by a moisture sensor mode, a timer mode, a forced mode, and a stop mode; And
And a timer unit for controlling an irrigation start time, a tubing quantity, and an irrigation time by a mode selected by a daily timer and an operation / relaxation timer. 10. The method of claim 9,
Wherein the water sensor mode compares the water tension of the soil and the water tension of the sensor attached to the signal input unit to determine the watering start point. 10. The method of claim 9,
Wherein the timer mode adjusts the operation of the output unit for a time input to the daily timer. 6. The method of claim 5,
Wherein the irrigation control device further comprises an irrigation pump that receives a signal from the output unit and operates according to the soil moisture requirement.

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