KR102593411B1 - Vinyl house having solar module - Google Patents

Abstract

The present invention relates to a greenhouse equipped with a vertical solar module to remove snow accumulated in the greenhouse using electricity produced through solar power generation and to minimize the loss of sunlight entering the greenhouse. .
A greenhouse equipped with a vertical solar module according to an embodiment of the present invention includes a plurality of vertical parts installed at a mutually preset interval on the ground, a plurality of arch parts installed on the upper side of the vertical parts, and between the vertical parts. A support portion consisting of a plurality of horizontal portions that maintain the spacing between arch portions and forming a greenhouse frame; a vinyl portion installed to surround the support portion; It consists of a double-sided power generation panel, a horizontal frame and a vertical frame provided to surround an edge of the double-sided power generation panel, and a plurality of solar modules installed on the upper side of the arch part; and a snow removal unit provided on one side of the arch part to remove snow accumulated in the arch part.
According to the present invention, the present invention has the advantage of continuously removing snow to prevent the greenhouse from collapsing due to heavy snow by circulating heated water through pipes provided inside the greenhouse. In addition, the heater for heating the water and the water pump for circulating the water are operated by electricity produced through a solar module installed on the top of the greenhouse, so it is environmentally friendly and can minimize the burden of electricity bills on farmers. In addition, the solar modules are installed perpendicular to the ground and spaced apart at a set interval in the width direction of the greenhouse, thereby not only minimizing the loss of sunlight entering the greenhouse, but also generating power by using sunlight reflected from the surface of the greenhouse. This has the effect of improving efficiency.

Description

Vinyl house having solar module}

The present invention relates to a greenhouse equipped with a vertical solar module to remove snow accumulated in the greenhouse using electricity produced through solar power generation and to minimize the loss of sunlight entering the greenhouse. .

In general, greenhouses are intended to grow vegetables and fruits regardless of the season, and transparent vinyl is used to allow sunlight to easily flow in and block external temperature to maintain a constant internal temperature.

When heavy snow falls in winter, a lot of snow accumulates in the greenhouse, and if the amount of snow exceeds the load limit of the frame, the greenhouse cannot withstand the weight of the snow and collapses.

Therefore, in order to prevent the collapse of greenhouses due to heavy snow, snow accumulation must be continuously removed. However, due to the situation in rural areas in Korea, not only is there an absolute shortage of manpower, but snow removal work is performed using brooms or snow removal boards, etc. There is a problem in that the snow removal effect is reduced significantly during short-term heavy snowfall due to significantly reduced performance.

KR 1884631 B1

The present invention heats water to a set temperature using electricity produced through solar power generation, flows the heated water through pipes provided in the greenhouse, and continuously removes snow accumulated in the greenhouse to create a greenhouse. The goal is to provide greenhouses equipped with vertical solar modules that prevent collapse.

In addition, the present invention provides a greenhouse equipped with a vertical solar module in which the solar module is installed perpendicular to the ground to minimize the loss of sunlight entering the greenhouse and not affect crop growth.

Additionally, the present invention provides a greenhouse equipped with a vertical solar module that can sell the remaining electricity used for snow removal.

A greenhouse equipped with a vertical solar module according to an embodiment of the present invention includes a plurality of vertical parts installed at a mutually preset interval on the ground, a plurality of arch parts installed on the upper side of the vertical parts, and between the vertical parts. A support portion consisting of a plurality of horizontal portions that maintain the spacing between arch portions and forming a greenhouse frame; a vinyl portion installed to surround the support portion; It consists of a double-sided power generation panel, a horizontal frame and a vertical frame provided to surround an edge of the double-sided power generation panel, and a plurality of solar modules installed on the upper side of the arch part; and a snow removal unit provided on one side of the arch to remove snow accumulated in the arch.

At this time, the solar modules are installed perpendicular to the ground on the upper side of the arch part, parallel to the longitudinal direction of the support part, and spaced apart at a set interval in the width direction of the support part to minimize the loss of sunlight incident on the inside of the greenhouse. It is characterized by

The snow removal unit consists of a pipe installed inside the plastic unit, a tank in which water is stored, a water pump that circulates water through the pipe, and a heater that heats the water stored in the tank.

At this time, the pipe is installed parallel to the longitudinal direction of the support part in the arch part and the inlet pipe through which the heated water flows in by the water pump, and uses the water flowing in from the inlet pipe to remove snow accumulated in the arch part. It is composed of a heat conduction pipe and an outflow pipe that transfers water flowing out of the heat conduction pipe to the tank.

In addition, the horizontal frame consists of a first horizontal frame located on the upper side of the double-sided power generation panel and a second horizontal frame located on the lower side, and the second horizontal frame is spaced upward from the vinyl portion at a set distance, Snow removed from the arch part flows down between the horizontal frame and the vinyl part.

A snow detection unit is provided on the outside of the arch to detect whether there is snow, and the snow detection unit includes a body, a plate-type first electrode provided on the body, and a plate-type first electrode provided on the body and spaced apart from the first electrode at a set distance. It consists of a second electrode formed at a set height, and is characterized in that snow cover is detected when the thickness of snow on the arch is greater than the set height.

The present invention has the advantage of continuously removing snow to prevent the greenhouse from collapsing due to heavy snow by circulating heated water through pipes provided inside the greenhouse.

In addition, the heater for heating the water and the water pump for circulating the water are operated by electricity produced through a solar module installed on the top of the greenhouse, so it is environmentally friendly and can minimize the burden of electricity bills on farmers.

In addition, the solar modules are installed perpendicular to the ground and spaced apart at a set interval in the width direction of the greenhouse, thereby not only minimizing the loss of sunlight entering the greenhouse, but also generating power by using sunlight reflected from the surface of the greenhouse. This has the effect of improving efficiency.

1 is a block diagram briefly showing the configuration of a greenhouse equipped with a vertical solar module according to an embodiment of the present invention.
Figure 2 is a front view of a greenhouse equipped with a vertical solar module according to an embodiment of the present invention.
Figure 3 is a side view of a greenhouse equipped with a vertical solar module according to an embodiment of the present invention.
4 is a diagram showing the detailed structure of a pipe according to an embodiment of the present invention.
Figure 5 is a diagram showing a structure in which piping is installed in a greenhouse equipped with a vertical solar module according to an embodiment of the present invention.
Figure 6 is a perspective view of a snow detection unit according to an embodiment of the present invention
Figure 7 is a flowchart briefly showing a method of snow removal using a greenhouse equipped with a vertical solar module according to an embodiment of the present invention.

Hereinafter, a greenhouse equipped with a vertical solar module according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 shows a block diagram briefly illustrating the configuration of a greenhouse equipped with a vertical solar module according to an embodiment of the present invention. Figure 2 shows a front view of a greenhouse equipped with a vertical solar module according to an embodiment of the present invention. Figure 3 shows a side view of a greenhouse equipped with a vertical solar module according to an embodiment of the present invention.

Looking at these drawings, a greenhouse equipped with a vertical solar module includes a support part 100 forming a frame, a vinyl part 200 provided to surround the support part 100, and an upper part of the support part 100. A solar module 300 installed perpendicular to the ground, a snow removal unit 400 provided on one side of the vinyl unit 200 to remove snow, and detection of whether snow has accumulated on the vinyl unit 200. It consists of a snow detection unit 500 for detecting the outside temperature, a temperature detection unit 600 for detecting the outside temperature, and an inverter 700 for converting the electricity produced from the solar module 300. At this time, the produced electricity can be self-consumed or sold.

The support portion 100 includes a plurality of vertical portions 110 installed at a predetermined interval apart from each other on the ground, a plurality of arch portions 120 installed on the vertical portion 110, and an interval between the vertical portions 110. It consists of a horizontal portion 130 that maintains the outer shape of the frame by maintaining the gap between the arch portion 120 and the arch portion 120.

At this time, the support part 100 can support the load of a plurality of solar modules 300 and the structure supporting them and is made of a durable pipe.

The solar module 300 consists of a double-sided power generation panel 310, a horizontal frame 320, and a vertical frame 330 provided to surround the edge of the panel.

The double-sided power generation panel 310 is provided parallel to the longitudinal direction of the support part 100.

The horizontal frame 320 is composed of a first horizontal frame 321 located above the double-sided power generation panel 310 and a second horizontal frame 322 located below.

The vertical frame 330 is installed on the upper side of the arch portion 120 and is composed of a plurality of vertical frames 330, which are formed in a set arrangement on the upper side of the support portion 100. The vertical frames 330 are formed side by side and spaced apart at a set interval in the length direction of the support part 100, and are also spaced apart at a set distance L1 in the width direction of the support part 100.

That is, the solar modules 300 are arranged parallel to the longitudinal direction of the support part 100, and are spaced apart at an interval L1 set to 2 m to 3 m in the width direction of the support part 100, so that the sun incident on the inside of the greenhouse Minimize light loss.

In addition, since sunlight reflected by the vinyl portion 200 located between solar modules 300 spaced apart by a set interval L1 is used, solar power generation efficiency is improved.

And the second horizontal frame 322 is formed upwardly from the vinyl portion 200 at a set distance L2, so that snow removed from the arch portion 120 is connected to the second horizontal frame 322 and the vinyl portion 200. ) flows down through the At this time, the set interval L2 is set to 10 cm or more so that the removed snow can easily flow down.

The snow removal unit 400 includes a pipe 410 installed on one side of the arch part 120, a tank 420 in which water is stored, a water pump 430 that circulates water through the pipe 410, and , It consists of a heater 440 that heats the water stored in the tank 420 to a set temperature. That is, the pipe 410 is located inside the vinyl portion 200.

FIG. 4 shows a diagram showing the detailed structure of the pipe 410 according to an embodiment of the present invention. Figure 5 is a diagram showing a structure in which piping is provided on one side of the arch according to an embodiment of the present invention.

Looking at these drawings, the pipe 410 includes an inflow pipe 411 through which heated water flows in by the water pump 430, and a device for removing snow using the water flowing in from the inflow pipe 411. It consists of a heat conduction pipe 412 and an outflow pipe 413 that transports water flowing out of the heat conduction pipe 412 to the tank 420.

The inlet pipe 411 and the outlet pipe 413 are provided in the area where the vertical part 110 is located, and the heat conduction pipe 412 is provided in the area where the arch part 120 is located. And the heat conduction pipe 412 is installed parallel to the longitudinal direction of the support part 100.

In the pipe 410 structure according to an embodiment of the present invention, the outlet pipe 413 is provided on the left and right sides of one inlet pipe 411, and a branch pipe 414 is connected to one end of the inflow pipe 411. And heat conduction pipes 412 are connected to the left and right sides of the branch pipe 414, respectively. The outlet pipes 413 are each connected to one end of the heat conduction pipe 412.

The inlet pipe 411, the outlet pipe 413, and the branch pipe 414 are wrapped with an insulating material to prevent heat from being transferred to the outside. And the heat conduction pipe 412 is made of a material such as copper with high heat conductivity.

Figure 6 shows a perspective view of the snow detection unit 500 according to an embodiment of the present invention. Looking at this, the snow detection unit 500 includes a body 510 provided on the upper side of the arch portion 120 and located outside the vinyl portion 200, and a plate-type first electrode provided on the upper side of the body 510 ( 520 and a second electrode 530 provided on the upper side of the body 510 and spaced apart from the first electrode 520 by a set distance.

The body 510 is provided with a wire that electrically connects the first electrode 510 and the second electrode 530. And the second electrode 530 has a set height L3.

In an embodiment of the present invention, the set height (L3) is set to 5 mm or more, and when the thickness of the snow on the arch portion 120 is 5 mm or more, current is generated through the first electrode 510 and the second electrode 520. flows and resistance is detected.

Figure 7 shows a flow chart briefly showing a method of snow removal using a greenhouse equipped with a vertical solar module according to an embodiment of the present invention.

Looking at this, a step in which electricity is produced by solar power generation (S100), a step in which the control unit determines whether the outside air detected by the temperature detection unit 600 is higher than the set temperature (S200), and the snow detection unit 500 A step (S300) in which the control unit determines whether the resistance detected is higher than the set resistance, and the heater 440 and the water pump 430 are operated so that the heated water in the tank 420 flows into the pipe 410. It consists of a step in which snow is removed by flowing (S400) and a step in which the generated electricity is transmitted to the sales line (S500).

Step S300 is performed when the outside air is lower than the set temperature in step S200, and step S400 is performed when the resistance detected in step S300 is higher than the set resistance.

The scope of the present invention should be construed as including all changes or modified forms derived based on the technical idea of the present invention in addition to the embodiments disclosed herein.

100: support part
110: vertical part
120: arch part
130: horizontal part
200: Vinyl part
300: solar module
310: Double-sided power generation panel
320: horizontal frame
321: first horizontal frame 322: second horizontal frame
330: Vertical frame
400: Snow removal department
410: piping
411: inlet pipe 412: heat conduction pipe
413: Outflow pipe 414: Branch pipe
500: Snow detection unit
510: body
520: first electrode
530: second electrode

Claims (3)

A greenhouse frame is composed of a plurality of vertical parts installed at a set interval from each other on the ground, a plurality of arch parts installed on the upper side of the vertical parts, and a plurality of horizontal parts that maintain the spacing between the vertical parts and the spacing between the arch parts. A support portion forming a;
a vinyl portion installed to surround the support portion;
It consists of a double-sided power generation panel, a horizontal frame and a vertical frame provided to surround the edge of the double-sided power generation panel, and is installed perpendicular to the ground on the upper side of the arch part and parallel to the longitudinal direction of the support part, and in the width direction of the support part. is a plurality of solar modules spaced apart at a set interval to minimize the loss of sunlight incident on the interior of the greenhouse;
a snow removal unit provided on one side of the arch to remove snow accumulated in the arch;
a snow detection unit provided on the outside of the arch part to detect whether there is snow; and
It consists of a temperature detection unit that detects the outside temperature,
The snow detection unit,
A body provided outside the vinyl portion,
A first electrode provided on the upper side of the body,
It is provided on the upper side of the body and is spaced apart from the first electrode at a set distance, and is formed 5 mm higher than the first electrode. It consists of a second electrode through which current flows between the first electrode and the first electrode when the thickness of the snow is 5 mm or more. ,
When the resistance of the current detected by the snow detection unit is higher than the set resistance and the outdoor temperature detected by the temperature detection unit is lower than the set temperature, the snow removal unit is operated,
A greenhouse equipped with a vertical solar module, characterized in that when the outside temperature is higher than the set temperature or the resistance is lower than the set resistance, the electricity produced by the solar module is transmitted to a line for sale. According to paragraph 1,
The snow removal department,
A pipe installed inside the vinyl portion,
A tank where water is stored,
A water pump that circulates water through the pipe,
Consisting of a heater that heats the water stored in the tank,
The pipe is,
an inflow pipe through which the heated water is introduced by a water pump;
A heat conduction pipe installed parallel to the longitudinal direction of the support portion in the arch portion and removing snow accumulated in the arch portion using water flowing in from the inflow pipe;
Consisting of an outflow pipe that transports water flowing out from the heat conduction pipe to the tank,
The horizontal frame is,
It consists of a first horizontal frame located on the upper side of the double-sided power generation panel and a second horizontal frame located on the lower side,
The second horizontal frame is spaced upward from the vinyl portion at a set interval, so that snow removed from the arch portion flows down between the horizontal frame and the vinyl portion.

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