KR101274199B1 - Solar cell power generating system provided with greenhouse for cultivation - Google Patents

Abstract

PURPOSE: A solar cell power generating system including a cultivation greenhouse is provided to facilitate installation by using a solar cell structure supported by a vertical support frame. CONSTITUTION: A greenhouse(300) is installed on the ground. The greenhouse includes a vertical support frame(310). A solar cell structure(100) is combined with the vertical support frame. At least one fan is installed in the solar cell structure. The solar cell structure forms an air flow toward a solar cell module by using the fan. [Reference numerals] (AA) South; (BB) North; (CC) Cultivation greenhouse

Description

Solar cell power plant with crop cultivation room and construction method {Solar cell power generating system provided with greenhouse for cultivation}

The present invention relates to a solar cell power generation facility, and more particularly, to a solar cell power generation facility that produces electricity using solar light.

Photovoltaic power generation is one of solar energy generation technologies, and converts solar light energy directly into electrical energy using a photoelectric converter called a solar cell.

A solar cell is a device that can convert solar energy into electrical energy. When light of energy greater than the prohibition band is irradiated to a semiconductor junction region having a PN junction surface, electrons and holes are generated to generate an internal electric field formed in the junction region. Electrons move to the N-type semiconductor and holes move to the P-type semiconductor to generate electromotive force.

Photovoltaic power generation using solar cells is attracting attention as an alternative energy source due to depletion of fossil fuel oil, global warming, etc. Solar cell power generation using batteries is rapidly spreading.

However, in the case of photovoltaic power generation using solar cells, a space for stably installing the solar cells, that is, a large area of installation site is required, but the installation site where the solar cell power generation facilities are installed is used for purposes other than solar power. There is this.

It is an object of the present invention to understand the characteristics of the solar cell power generation facilities as described above, including a solar cell that can grow crops, such as crops, along with power generation using solar cells, as well as photovoltaic power generation solar cell power generation facilities And to provide a construction method thereof.

The present invention has been created to achieve the object of the present invention as described above, the present invention is installed on the ground 10 to form a greenhouse 300 and the vertical support frame 310 of the greenhouse 300 Disclosed is a solar cell power generation facility comprising a solar cell structure (100) coupled to it.

The solar cell structure 100 includes a plurality of solar cell modules 110 to produce electricity from sunlight, and includes a plurality of solar cell modules 110; It includes a support frame portion 120 for supporting the solar cell module 110 so that the light receiving surface of the solar cell module 110 is substantially inclined toward the south, the support frame portion 120 is the greenhouse 300 It can be coupled to the vertical support frame 310 of.

The support frame part 120 may include a vertical frame that is supported and installed on an upper end of the vertical support frame 310 of the greenhouse 300.

The solar cell structure 100 may be provided with one or more fans on the surface facing north, thereby forming an air flow toward the solar cell module by the fan.

The solar cell structure 100 may be provided with one or more fans on the surface facing south, thereby forming an air flow toward the solar cell module by the fan.

An open portion 350 that is open toward the solar cell structure 100 may be installed at a portion facing south of the ceiling portion 340 of the greenhouse 300.

The opening 350 may be kept open or opened or closed manually or automatically by the opening and closing device 321.

The fan may be operated by electricity produced from the solar cell structure.

Further comprising a temperature sensor for measuring the temperature of the solar cell module 110, the operation of the fan 190 may be controlled to operate only in a predetermined temperature range.

The solar cell structure 100 is provided with a plurality of fans in the north facing surface, some of the fans may form an air flow toward the bottom surface of the solar cell module, the remaining air flow toward the greenhouse. .

The solar cell structure 100 is provided with one or more fans on the surface facing south, the fan may form an air flow toward the bottom surface of the solar cell module through the upper surface of the greenhouse.

As a construction method of a solar cell power generation facility having the configuration as described above, the solar cell structure is to be constructed by being coupled to the vertical support frame 310 of the greenhouse 300, which is pre-constructed before construction of the solar cell structure Disclosed is a method of constructing a solar cell power plant.

The solar cell structure 100 includes a plurality of solar cell modules 110 to produce electricity from sunlight, and includes a plurality of solar cell modules 110; It includes a support frame portion 120 for supporting the solar cell module 110 so that the light receiving surface of the solar cell module 110 is substantially inclined toward the south, the support frame portion 120 is the greenhouse 300 It may be coupled to at least one of bolting coupling and welding coupling to the vertical support frame (310).

Any one of the vertical frame 121 of the solar cell structure 100 and the vertical support frame 310 of the greenhouse 300 may be coupled to one part is inserted into the other in the vertical direction.

Solar cell power generation facility and its construction method combined with the crop cultivation according to the present invention by installing the solar cell structure 100 is supported on the vertical support frame 310 of the crop cultivation chamber 300 for crop cultivation The construction of the facility can be simplified, and the construction cost can be significantly reduced.

In particular, by using the vertical support frame 310 of the crop cultivation room 300 for the installation of the solar cell structure 100, the solar cell structure 100 when the construction of the solar cell power generation facility combined with the crop cultivation room (300) By reducing the height of the vertical frame 121 of the construction can be simplified, the construction cost can be significantly reduced.

In addition, the solar cell power generation facilities serving as crop cultivation according to the present invention is installed at least one fan in the north facing, by the air installed toward the solar cell module by the fan installed on the north facing in the case of high temperature summer Forming has the advantage to improve the solar cell efficiency by cooling the solar cell module.

In addition, the solar cell power generation facilities combined with crop cultivation according to the present invention is installed at least one fan in the south facing, by forming air flow toward the solar cell module relatively warm air by the fan in the winter when the temperature is low There is an advantage that can improve the solar cell efficiency by heating the solar cell module.

In particular, by opening a part of the ceiling of the crop cultivation room when forming the air flow by the fan installed on the south facing side, there is an advantage to improve solar cell efficiency by utilizing warm air in the greenhouse to heat the solar cell module.

1 is a side cross-sectional view showing a solar cell power plant according to the present invention.
2 is a side cross-sectional view showing a state in which a shield is wound in the solar cell power generation facility of FIG. 1.
3 is a conceptual diagram illustrating a construction method of the solar cell power generation facility of FIG. 1.

Hereinafter, a solar cell power plant according to the present invention and a construction method thereof will be described in detail with reference to the accompanying drawings.

1 and 2, the solar cell power generation facility according to the present invention is installed on the ground 10, the crop cultivation room 300 and the crop cultivation room 300 to form a greenhouse for crop cultivation It includes a solar cell structure (100) coupled to the vertical support frame (310).

The crop cultivation heating chamber 300 is installed on the ground (10) as a configuration for the cultivation of crops such as mushrooms (mushroom cultivator), vegetables, such as shiitake mushrooms can be configured in various ways.

Herein, the crops grown by the crop cultivation chamber 300 are more preferably crop plants, which are not exposed to direct sunlight, as much as possible, rather than crops that require direct sunlight.

In particular, the crop cultivation room 300 may be installed by at least one of vinyl and glass, and a light control member (not shown) for adjusting the light of the light may be additionally installed.

For example, the crop cultivation room 300 may form an outer wall by a PE film, a heat insulating material, a light shielding net.

In addition, the crop cultivation room 300 may be additionally installed in the ventilation facility (not shown) such as a fan so that the inside and the outside is ventilated.

Meanwhile, the crop cultivation room 300 includes a plurality of vertical support frames 310 installed vertically for installation of the solar cell structure 100 to be described later.

The vertical support frame 310 forms a skeleton of the crop cultivation chamber 300 and also supports the solar cell structure 100 and stably supports the solar cell structure 100 such as steel structures such as H-beams. Any structure can be used as long as the structure and material are possible. The vertical support frame 310 may be fixed to the support structure 311 installed on the ground (10).

In particular, the crop cultivation room 300, as well as the solar cell structure 100 may have a light steel structure, that is, a LEB system (Lightweight pre-engineered building system).

On the other hand, the crop cultivation room 300 may be installed to support the ceiling portion 340 to the plurality of horizontal frames 320 for the light of the sunlight. At this time, a part of the ceiling portion 340, in particular, the portion facing south may be provided with an opening portion 350 that opens toward the solar cell structure 100 to be described later.

The ceiling portion 340 may have a variety of shapes according to the structure of the crop cultivation room 300, as shown in Figure 1 and 2, may have a variety of shapes, such as '^' shape in consideration of the drainage. have.

The opening part 350 may be kept open or may be opened or closed manually or by a separate opening and closing device 321 such as a slide or a roll.

Meanwhile, the crop cultivation heating chamber 300 is shielded by at least some of the front, rear, and side surfaces of the crop cultivation heating chamber 300 by the shielding parts 331 and 332.

The shielding parts 331 and 332 may use various members such as a black film that can transmit light or block light transmission according to seasons and crops.

In addition, the shielding parts 331 and 332 need to be ventilated with the outside at the time of season, crop cultivation, as shown in FIG. Can be.

On the other hand, the crop cultivation heating room 300 can be utilized as a breeding facility for breeding animals as well as plants.

The solar cell structure 100 includes a plurality of solar cell modules 110 to produce electricity from sunlight, and includes a plurality of solar cell modules 110; It is configured to include a support frame 120 for supporting the solar cell module 110 so that the light receiving surface of the solar cell module 110 substantially inclined toward the south.

The solar cell module 110 is composed of a plurality of solar cell elements for converting solar energy into electrical energy and can be configured in various ways according to the configuration of the solar cell, and a plurality of solar cell elements and solar cell elements in general. It may be composed of a plurality of frame members for configuring as one module.

The solar cell module 110 is preferably installed to receive as much sunlight as possible, and in consideration of the solar altitude, the solar cell module 110 may be inclined at 25 ° to 45 ° based on a horizontal plane of the ground 10.

The support frame unit 120 may be any configuration as long as it is a configuration for supporting the solar cell modules 200 as a configuration for supporting the solar cell modules 200.

The support frame portion 120 may be installed in various structures, for example, as shown in Figures 1 and 2, may form a truss structure.

For example, the support frame unit 120 is installed at one or more vertical frames 121 and vertical frames 121 installed on the ground 10 and supported to support the solar cell module 110. It may be configured to include a support frame 122.

The vertical frame 121 may be installed to be supported on the vertical support frame 310, in particular the upper end of the above-described crop cultivation room 300.

For example, the vertical frame 121 may be installed in various forms such as bolt coupling, welding coupling to the vertical support frame 310 of the crop cultivation room 300 is already installed.

That is, the vertical frame 121 of the solar cell structure 100 is located on the vertical support frame 310 of the crop cultivation chamber 300, as shown in Figs. 1 and 3, the coupling member 122 ) And the bolt 123 can be firmly coupled.

Here, any one of the vertical frame 121 of the solar cell structure 100 and the vertical support frame 310 of the crop cultivation room 300 is inserted into the other one in the vertical direction for a more firm coupling desirable.

In addition, the vertical frame 121 of the solar cell structure 100 and the vertical support frame 310 of the crop cultivation room 300 may be combined using both welding and bolting coupling for a more robust coupling when mutually coupled. .

As described above, when the vertical frame 121 for supporting the solar cell module 110 is coupled in various forms such as bolt coupling, welding coupling to the vertical support frame 310 of the crop cultivation room 300, the crop cultivation room When installed on the (300) there is an advantage that can significantly reduce the construction cost for the installation of the solar cell structure 100 by reducing the vertical length of the vertical frame 121.

In addition, the module support frame 122 is supported by the vertical frame 121, the solar cell module 110 is inclined relative to the horizontal plane of the ground 10, that is installed toward the sun.

The vertical frame 121 and the module support frame 122 is a bar-shaped member is welded or assembled so that sunlight can be transmitted to the crop cultivation room 300 in a portion where the solar cell module 110 is not installed desirable.

On the other hand, the support frame 120 is installed at least one auxiliary frame 123 connecting the module support frame 122 and some of the vertical frame 121 to support the module support frame 122 more stably Can be.

The auxiliary frame 123 is configured to reinforce the support for the module support frame 122, and any structure can be provided as long as it can stably support the solar cell module 110.

Meanwhile, as shown in FIGS. 1 and 2, the solar cell structure 100 is coupled to the support frame part 120 to generate one or more fans 190 to generate air flow under the solar cell module 110. It may further include.

The fan 190 is a configuration for generating air flow in the lower side of the solar cell module 110, any configuration can be formed if the air flow can be formed. The fan 190 may be operated by electricity produced by the solar cell module 110.

In addition, the fan 190 may be selected an appropriate number and position for forming air flow in the lower side of the solar cell module 110.

In particular, the fan 190 may be installed at the rear toward the north side of the solar cell structure 100 to form an air flow toward the front. The fan 190 is more preferably installed to form an air flow toward the bottom side of the solar cell module 110.

As described above, when the fan 190 is installed in the rear toward the north of the solar cell structure 100, relatively cool air flows toward the bottom of the solar cell module 110 to cool the solar cell module 110, hot summer As described above, the temperature of the solar cell module 110 may be lowered in a high temperature environment to improve the efficiency of the solar cell module 110.

In addition, when the fan 190 is installed in the rear toward the north of the solar cell structure 100, a part of the air flow flows through the upper surface of the crop cultivation room 300, also cooling the crop cultivation room 300 to some extent Can have

At this time, the crop cultivation room 300 may be partially or automatically opened so that the inside of the crop cultivation room 300 can be efficiently cooled by the air flow formed by the fan 190.

That is, a plurality of fans 190 are installed in the rear toward the north of the solar cell structure 100, some of the fans 190 to the air flow toward the bottom of the solar cell module 110, the other crops An air flow toward the upper surface of the cultivation greenhouse 300 may be formed.

Here, the air flow toward the upper surface of the crop cultivation room 300 may pass to the bottom of the solar cell module 110 after passing through the top surface of the crop cultivation room 300.

Meanwhile, the fan 190 may be installed at the front of the solar cell structure 100 facing south to form air flow toward the rear. The fan 190 is more preferably installed to form an air flow toward the bottom side of the solar cell module 110.

In particular, the fan 190 passes through the top surface of the crop cultivation room 200 to form an air flow toward the bottom side of the solar cell module 110 to cover the top surface of the crop cultivation room 200 when the temperature is low, such as winter. After roughing, the heating effect of the solar cell module 110 may be maximized by facing toward the bottom of the solar cell module 110.

As described above, when the fan 190 is installed in the front toward the south of the solar cell structure 100, relatively hot air flows toward the bottom of the solar cell module 110 to heat the solar cell module 110 By heating the solar cell module 110 in a low temperature environment, such as low winter, the efficiency of the solar cell module 110 can be improved.

In addition, when the fan 190 is installed in the front of the solar cell structure 100 toward the south, a part of the air flow flows through the upper surface of the crop cultivation room 300 also has the effect of heating the crop cultivation room 300 to some extent Can have

In addition, a part of the ceiling part 340 of the crop cultivation room 300, in particular, the part facing south is provided with an opening 350 to be opened toward the solar cell structure 100 to be described later, the fan 190 is a solar cell Installed in front of the structure 100 toward the south, the solar cell module in the cold winter receives hot air from the crop cultivation room 300 from the crop cultivation room 300 by the air flow formed by the fan 190 Heating 110 may maximize the efficiency of the solar cell module 110.

In addition, when the fan 190 is installed in front of the south, the opening part 350 is automatically opened and closed so that the opening part 350 is automatically opened only when the fan 190 is operated, and thus from the crop cultivation chamber 300. By receiving hot air in the crop cultivation room 300, the solar cell module 110 may be heated in a cold winter to maximize the efficiency of the solar cell module 110.

On the other hand, the fan 190 is mainly intended to improve the power generation efficiency of the solar cell module 110, which is suitable for high temperature or low temperature environment bar temperature sensor for measuring the temperature of the solar cell module 110 (not shown) It can be added to control the operation of the fan 190 to operate only in a predetermined temperature range.

In addition, the fan 190 is intended for cooling the solar cell module 110 in the summer when the temperature is low and heating the solar cell module 110 in the winter when the temperature is high, the lower side of the solar cell structure 100 Although the greenhouse 300 installed at the premise is a high temperature environment, the greenhouse 300 may have various forms such as a low-temperature environment in the summer and a high-temperature environment in the winter by forming a thermal insulation, that is, an insulation structure.

In this case, the fan 190 installed in the south, that is, the front side is cooled by a part of the low temperature air from the open portion 350 of the greenhouse 300 in a low temperature environment and flows to the bottom of the solar cell module 110 to provide a solar cell module ( 110 may be utilized for cooling.

In addition, the fan 190 installed at the north, ie, the rear side, is heated by a part of the high temperature air from an open portion (not shown) of the greenhouse 300 in a high temperature environment and flows to the bottom of the solar cell module 110 to provide a solar cell module ( 110 may be utilized for heating.

Meanwhile, in the solar cell power generation facility according to the present invention, except that the crop cultivation room 300 and the solar cell structure 100 are installed all at once, as shown in FIG. 3, the crop cultivation room 300 is already installed or After the crop cultivation room 300 is installed in advance, it is installed and installed so that the solar cell structure 100 is supported on the vertical support frame 310 of the crop cultivation room 300.

As described above, by installing the solar cell structure 100 to be supported in the vertical support frame 310 of the crop cultivation room 300, which is already installed or constructed first for the installation of the solar cell structure 100, the construction cost Significant savings can be made.

That is, the vertical support frame 310 of the crop cultivation room 300 is utilized as a support structure for the support of the solar cell structure 100, the solar cell structure is installed at a relatively higher position than the crop cultivation room 300 It is possible to reduce the construction cost by reducing the height of the frame for the support of (100).

In addition, during the construction of the solar cell power generation facilities, the crop cultivation room 300 is constructed on the ground 10, and at the same time, the solar cell structure 100 is assembled at another place, and then the vertical support frame of the crop cultivation room 300 is constructed. By installing the solar cell structure 100 to be supported at 310, there is an advantage that can significantly reduce the overall construction cost by reducing the construction time.

In addition, by using the vertical support frame 310 of the crop cultivation chamber 300 has been installed irrespective of the solar cell structure 110 when the construction of the solar cell power generation facility to support the structure of the solar cell structure (110). When the vertical support frame 310 is provided in the crop cultivation room 300, the construction of the solar cell structure 110 is possible, and thus there is an advantage of enabling the existing structure as a facility for solar cell power generation.

Here, if the structure is provided with a vertical support frame 310 for the support of the solar cell structure 110, both the crop cultivation room 300, as well as the house, livestock company.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100: solar cell structure
110: solar cell module 120: support frame portion
300: crop cultivation chamber 310: vertical support frame

Claims (14)

It includes a greenhouse 300 is installed on the ground 10 to form a greenhouse, and the solar cell structure 100 is coupled to the vertical support frame 310 of the greenhouse 300,
The solar cell structure 100 is a solar cell power generation facility, characterized in that the air flow toward the solar cell module by the fan by installing one or more fans on the surface facing north. It includes a greenhouse 300 is installed on the ground 10 to form a greenhouse, and the solar cell structure 100 is coupled to the vertical support frame 310 of the greenhouse 300,
The solar cell structure 100 is a solar cell power generation facility, characterized in that by installing at least one fan on the surface facing south, to form an air flow toward the solar cell module by the fan. The method according to claim 1 or 2,
The solar cell structure 100 includes a plurality of solar cell modules 110 to produce electricity from sunlight, and includes a plurality of solar cell modules 110; It includes a support frame portion 120 for supporting the solar cell module 110 so that the light receiving surface of the solar cell module 110 is substantially inclined toward the south,
The support frame portion 120 is a solar cell power generation facility, characterized in that coupled to the vertical support frame 310 of the greenhouse (300). The method according to claim 3,
The support frame portion 120 is a solar cell power generation facility, characterized in that it comprises a vertical frame that is supported and installed on the top of the vertical support frame 310 of the greenhouse (300). delete The method according to claim 2,
The solar cell power generation facility, characterized in that the opening portion 350 is opened to the south side of the ceiling portion 340 of the greenhouse 300 is opened toward the solar cell structure (100). The method of claim 6,
The opening part 350 is maintained in the open state, or the solar cell power generation facility, characterized in that the opening and closing by manual or automatic by the switchgear (321). The method according to any one of claims 1, 2 and 6 to 7,
The fan is a solar cell power generation facility, characterized in that the operation by the electricity produced from the solar cell structure. The method according to any one of claims 1, 2 and 6 to 7,
Further comprising a temperature sensor for measuring the temperature of the solar cell module 110,
The solar cell power generation facility, characterized in that the operation of the fan 190 is controlled to operate only in a predetermined temperature range. It includes a greenhouse 300 is installed on the ground 10 to form a greenhouse, and the solar cell structure 100 is coupled to the vertical support frame 310 of the greenhouse 300,
The solar cell structure 100 is installed by a plurality of fans in the surface facing north,
And some of the fans form air flows toward the bottom of the solar cell module, and the others form air flows toward the greenhouse. It includes a greenhouse 300 is installed on the ground 10 to form a greenhouse, and the solar cell structure 100 is coupled to the vertical support frame 310 of the greenhouse 300,
The solar cell structure 100 is one or more fans are installed on the surface facing south, the fan is a solar cell power generation facility, characterized in that to form an air flow toward the bottom surface of the solar cell module through the upper surface of the greenhouse. . As a method for constructing a solar cell power plant according to any one of claims 1, 2, 6, 7, 10 and 11,
The solar cell structure is pre-constructed after the construction of the solar cell power generation facility, characterized in that the construction is coupled to the vertical support frame 310 of the greenhouse 300 before the construction of the construction. The method of claim 12,
The solar cell structure 100 includes a plurality of solar cell modules 110 to produce electricity from sunlight, and includes a plurality of solar cell modules 110; It includes a support frame portion 120 for supporting the solar cell module 110 so that the light receiving surface of the solar cell module 110 is substantially inclined toward the south,
The support frame portion 120 is a construction method of a solar cell power generation facility, characterized in that coupled to at least one of the bolting coupling and welding coupling to the vertical support frame 310 of the greenhouse (300). The method according to claim 13,
Any one of the vertical frame 121 of the solar cell structure 100 and the vertical support frame 310 of the greenhouse 300 is inserted into the other part in the vertical direction, the solar cell power generation facility, characterized in that combined Construction method.

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