KR102077549B1 - Solar generating apparatus for farming - Google Patents

Abstract

The present invention relates to a solar power generation device for farming which can increase solar power generation efficiency. The solar power generation device for farming comprises: a pillar installed in furrows; and an arm having solar panels at both ends and mounted on the pillar, wherein an inclined gradient is adjusted in the pillars so that shadows of the solar panels are respectively formed in the furrows.

Description

Solar generating apparatus for farming

The present invention relates to a solar photovoltaic device for farming that does not interfere with the production of crops by the photovoltaic module while improving photovoltaic power generation efficiency.

Recently, due to the abnormal climate phenomenon caused by global warming problems, natural disasters around the world are suffering. This is due to the emissions of carbon dioxide from the use of fossil fuels, and efforts are being made to reduce carbon dioxide emissions worldwide.

However, as the industry develops and civilization develops, the amount of energy consumed by mankind increases exponentially. Therefore, the demand and utilization of infinitely clean alternative energy is increasing.

Photovoltaic power generation system using photovoltaic energy among alternative energy is energy that can be supplied almost infinitely, and it is being used around the world, and it is using current produced by installing in various industrial facilities as well as general homes.

Such solar power generation systems are rapidly increasing in demand in farms in which modernization is in progress. In the case of general farming solar power generation systems, foundation concrete structures and foundations protruding to the outside of farmland are installed at a set depth on the surface of farmland. It is connected to the concrete structure and installed, and has a set height, the horizontal beam is installed on the column, the horizontal beam is installed in the horizontal beam and the solar module is installed in the middle.

However, the conventional farming photovoltaic power generation system has the advantage of securing sufficient land area for farming by having a strut-type structure, but it damages the surrounding environment such as crops and housekeeping because it is directly installed as a new structure on the ground of farmland. In particular, the shading occurs due to the holding structure or the solar module coupled thereto according to the time-varying sunlight, and the shading acts as a factor that inhibits the growth of the crop by preventing sunlight from occurring. have.

In addition, since the conventional agricultural photovoltaic power generation system does not have a rotating structure in which the solar module is interlocked with the incident angle to the solar light, power generation is performed only within a limited time at a fixed position, thereby ensuring sufficient power generation efficiency. There is a problem.

Republic of Korea Patent No. 10-1539278

Accordingly, the present invention has been made to solve the problems of the prior art as described above, and to provide a farming photovoltaic device that does not interfere with the production of crops while increasing the photovoltaic power generation efficiency.

Agricultural solar power generation device of the present invention (hereinafter referred to as "device of the present invention") is a post installed in the furrow; Solar panels are configured at both ends and mounted on the posts, respectively, the arms of which the inclined gradient is adjusted on the posts so that the shadows of the solar panels are formed on the furrows, respectively.

As an example, the arm is characterized in that the height is configured to be adjusted in the post.

As an example, the pillar includes a pillar portion having a lower end fixed to the furrow and a receiving plate forming a pair of gaps at an upper end of the pillar portion, and having a plurality of fastening holes formed therein, wherein the arms each have a solar panel configured at an end thereof. And a insertion plate connected to the branch pipe and the branch pipe and disposed between the pair of receiving plates and formed with a plurality of through holes opposed to the fastening holes, and passing through the fastening holes and the through holes in the post. The arm is characterized in that the fixing bar is configured to be fixed while the slope is formed.

As an example, the pillar part is formed with a hollow inside and an inflow part for introducing cold from the ground is formed in a portion embedded in the ground, and the branch pipe is formed with a hollow inside and communicates with the hollow of the pillar part, each branch pipe The discharge hole is formed at the end of the cold air in the ground flows from the column portion is characterized in that the discharge through the discharge hole to the back of each solar panel.

As an example, a first opening is formed between the receiving plates at an upper end of the pillar, and the insertion plate has a space formed therein, and communicates with the hollow of the branch pipe at both sides, and communicates with the first opening at the bottom. An opening is formed, and the cold air flowing from the pillar portion flows through the hollow of each branch pipe through the insertion plate, and is discharged to the rear surface of each solar panel through each discharge hole.

As an example, the support may include a first rotating roller and a second rotating roller rotatably installed at the upper end and the lower end, respectively, and one end of which is connected to the selected one side of the arm and the other side of the post via the first rotating roller. A wire is connected to the rotating roller and the rotating handle connected to the rotating shaft of the second rotating roller and exposed to the outside of the support, wherein the arm has a central portion at the lower position than the first rotating roller It is characterized in that the hinge is configured to rotate.

As an example, the fixing plate is coupled to be exposed to the center of the arm, and a plurality of fixing holes are spaced apart along the direction of rotation of the arm, and the insertion hole and the fixing hole are formed through a portion of the support facing the selected fixing hole. Is fastened to the insertion hole through the ball is configured to fix the fixed plate is characterized in that for fixing the rotation angle of the adjusted arm.

As described above, the device of the present invention has the advantage that the photovoltaic power generation is made in pairs without hindering the solar irradiation due to the solar panel on the crops cultivated in the furrow has the advantage of increasing the power generation efficiency.

In addition, the device of the present invention can adjust the height of the device according to the crop, especially in the case of typhoons, such as by lowering the device as much as possible to improve the resistance to destruction of the device due to the typhoon, safety problems by detachment of the solar module, etc. There is an advantage.

In addition, the apparatus of the present invention has the advantage of controlling the thermal load of the solar panel using the cold in the ground.

1A, 1B, 1C are schematic diagrams showing the apparatus of the present invention,
2 and 3 is an operating state diagram for the device shown in Figures 1a, 1b, 1c,
4 is an operational state diagram of another embodiment of the present invention,
5 is a detailed configuration diagram of the embodiment shown in FIG. 4,
6 is an operational state diagram of another embodiment of the present invention,
FIG. 7 is a side cross-sectional view of a portion of the embodiment shown in FIG. 6.

Hereinafter, preferred embodiments of the present invention will be described.

Apparatus 1 of the present invention includes a support (2) installed in the furrow (a) as shown in Figure 1a; The solar panel 31 is configured at both ends and mounted on the support (2), the inclination gradient is adjusted in the support (2) so that the shadow of the solar panel 31 is formed in each furrow (a) (3); characterized by including.

That is, according to the present invention, a pair of photovoltaic panels 31 are formed on one support 2 to increase the photovoltaic power generation efficiency while the arm 3 including the photovoltaic panels 31 is formed on the support 2. The slope gradient (α) is adjusted so that the shade by the solar panel 31 is generated only in the furrows (a) at both ends of the furrows (b) so as not to interfere with the sunshine of the crops (c) cultivated in the furrows (b). There is a characteristic to avoid.

The pillar (2) is installed along the furrow (a) as the pillar (2) is installed as a plurality of furrows (a) as a pillar to install the windbreak according to the type of crops cultivated in the furrow (b) May be used.

The arm 3 is configured so that the solar panel 31 is formed at both ends and hinged from the support (2) to adjust the inclined gradient (α), as mentioned above in the solar panel 31 Shading by the furrows on both ends of the furrows (b) is to occur only in furrows (a).

As shown in Figure 2 for the expression of this function arm 3 is installed to enable rotational interlocking in the support (2) bar for this purpose is configured, the fixing means (4) is a support ( 2) and a mounting plate 41 fixed to one side of the clamp 42 and the clamp 42 is characterized in that it comprises.

The clamp 42 is a well-known configuration, the reference number is not shown, but is to be fixed at a predetermined position of the support (2) by a bolt or the like, and by the configuration of the clamp 42, the arm (3) is a support ( The height is adjusted in 2). The reason for adjusting the installation position in the support (2) of the arm (3) is that the installation position is adjusted so as not to interfere with the growth of the crop depending on the type of crops cultivated in the furrows (b), in particular by the typhoon In the event that destruction of the optical panel 31 or the like, secondary damage due to detachment or the like is expected, as shown in FIG. 1B, the arm 3 is lowered to the ground as much as possible in the support 2 to protect the device from such problems. You can do it.

The arm 3 is provided with a rotating plate 32 in the center portion, the rotating plate 32 is mounted so as to be rotatable to the mounting plate 41, the inclination of the arm 3 in the support (2) The gradient is to be adjusted.

Since the rotating plate 32 is fixed to the mounting plate 41 so as to be rotatable, there are various known techniques, and thus, detailed description thereof will be omitted, and the rotating plate 32 is mounted on the mounting plate ( In the case of the configuration fixed to 41, various known techniques exist, so the detailed description thereof will be omitted.

As another example, the arm 3 may be individually mounted at both ends of the hinge axis coupled to the support 2 so that the inclination gradient α may be independently implemented at both ends.

Accordingly, as shown in FIG. 1C, both ends of the arm 3 may be folded from the hinge axis to protect the device from damage caused by typhoons and strong winds.

In addition, the arm 3 may be configured to adjust the length as shown in FIG. 3, and the solar panel 31 configured in the arm 3 may be configured to adjust the angle by hinge coupling. As described above, the rotation angle and length are adjusted according to various sizes of crops, field crops (b) sizes, and the like, as mentioned above, without disturbing the irradiation of the sun on crops (c) cultivated in the crops (b). To make this happen.

Meanwhile, in the present invention, as shown in FIGS. 4 and 5, the arm 3 is mounted to adjust the inclination gradient in the support 2, and at the same time, the thermal load of the solar panel 31 is prevented by using a cold in the ground. An embodiment is provided to enable this.

In the present embodiment, the support (2) is spaced in pairs at the upper end of the pillar portion 21 and the pillar portion 21 is fixed to the furrow and the receiving plate 22 is formed with a plurality of fastening holes 221 And the arm 3 is connected to the pair of branch pipes 33 and the branch pipes 33, each of which has a solar panel 31 at an end thereof, between the pair of receiving plates 22. The insertion plate 34 is provided and is formed with a plurality of through holes (341) opposed to the fastening hole (221), and through the fastening hole 221 and the through hole (341) the support (2) The arm 3 is characterized in that the fixing bar 6 is configured to be fixed while the inclined gradient is formed.

In the present embodiment, the support (2) is composed of a pillar portion 21, the lower end is embedded in the furrow (a) and the plurality of fastening holes 221 at the edge of the column portion 21 in the shape of a disc in the drawing A pair of receiving plates 22 are formed.

In addition, the arm 3 is composed of a pair of branch pipes 33 protruding in both directions from the insertion plate 34 and the insertion plate 34 at the center, each of which is composed of a photovoltaic panel 31 at the end. Insertion plate 34 is configured to have a circular cross-section in the configuration in the configuration placed between the pair of receiving plate 22 at the top of the column portion 21, a plurality of penetrations facing the fastening hole 221 Ball 341 is formed.

In this way, after adjusting the inclined gradient of the arm (3) in the state in which the arm (3) settled on the support (2), the fixing bar (6) in the opposite fastening hole 221 and through hole (341) By inserting the arm (3) in the support (2) is to be fixed in a state where a certain gradient is formed.

In the structure, the pillar portion 21 has a hollow formed therein, and an inflow portion 23 for introducing cold from the ground is formed in a portion embedded in the ground, and the branch pipe 33 has a hollow formed therein. It communicates with the hollow of the pillar portion 21 and the discharge hole 331 is formed at the end of each branch pipe 33 so that the cold air flowed from the pillar portion 21 through each of the discharge hole 331 It is characterized in that the discharge to the back of the solar panel (31).

The inflow portion 23 is configured at the lower end of the column portion 21, the mesh is formed in the flow path penetrating the inner and outer, preventing the soil from flowing into the inside (g) of the ground (g) is the column portion 21 ) To flow into the interior. The cold inflow of the ground (g) flows up through the hollow of the pillar portion 21 to be discharged to the discharge hole 331 formed at the end through the hollow of each branch pipe (33).

The operation of this mechanism is convection as the temperature of the air in the pillar portion 21 and the branch pipe 33 rises during the summer, such that the air inside is discharged to the discharge hole 331. Negative pressure is formed in the hollow of the column part 21 and the branch pipe 33 as it flows out into the discharge hole 331, and this negative pressure flows into the inlet 23 to inhale the cold air g in the ground. (g) flows through the hollow of the pillar portion 21 and the branch pipe 33 to be discharged to the discharge hole 331. By this discharge, the cold limit g of the ground continues with the same operation mechanism. The discharge is to be made.

In this way, the underground cold (g) is sprayed to the rear surface of the solar panel 31 without any power source to prevent the thermal load of the solar panel 31 to facilitate the maintenance and management as well as the power generation efficiency.

A first opening 211 is formed between the receiving plate 22 on the top of the pillar portion 21 for such an operation mechanism, and the insertion plate 34 has a space formed therein and the branch pipe 33 on both sides. The second opening 342 is formed in communication with the first opening 211 at the bottom and communicates with the hollow of the hollow through the insertion plate (34) Flow through the hollow of each branch pipe 33 is to be discharged to the back surface of each solar panel 31 through each discharge hole 331. That is, the pillar portion 21 and the insertion plate 34 communicate with each other by the first opening 211 and the second opening 342, and each branch pipe 33 in the insertion plate 34 has a structure in communication. The whole device has a structure in communication, so that a structure in which cold in the ground is discharged through the discharge hole 331 is formed.

In another embodiment, the support 2 has a first rotary roller 51 and a second rotary roller 52 rotatably installed at the upper end and the lower end, respectively, and one end thereof is connected to the selected one side of the arm 3. The other side is interlocked with the wire 53 connected to the second rotating roller 52 via the first rotating roller 51 and the rotating shaft of the second rotating roller 52 and interlocked with each other. Rotation knob 54 is exposed to the outside, the arm (3) may be configured to rotate in the center hinged to the support (2) in a lower position than the first rotary roller (51). .

As shown in FIG. 6, the arm 3 is capable of adjusting a gradient in conjunction with the wire 53, the first rotating roller 51, and the second rotating roller 52.

Specifically, the wire 53 is connected to the selected side of the arm 3, and the other side is connected to the second rotating roller 52 via the first rotating roller 51. Configure to change direction flexibly.

At this time, since the rotary knob 54 is connected to the rotary shaft of the second rotary roller 52 to interlock, the arm (3) by rotating the rotary knob 54 to adjust the length of the wire 53 The gradient can be adjusted.

The wire 53 may be configured to be connected to the first rotary roller 51 and the second rotary roller 52 through the inside of the support (2). Such a configuration can protect the wire 53 from damage due to weathering caused by typhoon, rainy season, and the like.

The center of gravity on one side of the arm (3) to which the wire (53) is connected to enable a stable interlocking, such a structure to support the load of the arm (3) to have a structural stability.

The arm 3 is configured such that the central portion is hinged to the support 2 to rotate at a lower position than the first rotary roller 51, in which case the height is too low from the ground of the arm 3 Since it cannot be sufficiently rotated by the ground, it is preferable to select the position so that the arm 3 can be easily rotated.

If the damage caused by strong winds such as typhoons are concerned, it is possible to reduce the damage caused by strong winds by winding the wire 53 sufficiently close to the position parallel to the support (2).

The above structure can be maintained while maintaining the gradient set by the user in the absence of external influences, but in the actual environment there are various external influences caused by wind, rain or animals and people. It is difficult for the arm 3 to maintain a stable state.

In order to solve this problem, the fixing plate 35 is coupled to be exposed to the center of the arm 3, the plurality of fixing holes 351 are formed spaced apart along the rotation direction of the arm 3, and the selected one fixing hole A fixing bar 6 which is fastened to the insertion hole 23 through the insertion hole 23 and the fixing hole 351 formed through a portion of the support 2 facing the 351 to fix the fixing plate 6. ) May be configured.

The fixing hole 351 follows the direction of rotation of the arm 3 so that all the fixing hole 351 can correspond to the insertion hole 23, the hinge of the arm 3 as the center point It is preferable to form the plurality of fixing holes 351 spaced apart in the circumferential direction including the insertion hole 23.

As shown in FIG. 7, the fixing bar 6 may be inserted into the insertion hole 23 through the fixing hole 351 to be long enough to prevent the arm 3 from rotating and to be fixed. . In addition, it is preferable that the fixing bar 6 is selected from a material having a high strength so as to withstand the weight of the arm 3 and other loads due to external action.

By having such a structure, there is no change in the inclination gradient α of the arm 3 even by an external force, and sufficient energy can be secured through the solar panels 31 at both ends of the arm 3, respectively.

In addition, although not shown in the drawings, the fixing bar 6 may use a bolt or a screw. In this case, when the screw is used as the fixing bar 6, it is preferable that the corresponding insertion hole 23 also forms a screw line.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

1 Device of the Invention 2
21: pillar portion 211: first opening
22: receiving plate 221: fastening hole
23: insertion hole
3: arm 31: solar panel
32: rotating plate 33: branch pipe
331: discharge hole 34: insertion plate
341 through hole 342 second opening
35: fixing plate 351: fixing hole
4: fixing means 41: mounting plate
42: clamp 51: first rotating roller
52: second rotating roller 53: wire
54: rotation handle 6: fixed bar

Claims (7)

Props installed in furrows; And
A solar panel configured at both ends and mounted on the support, the arm having an inclined gradient adjusted on the support so that the shadow of the solar panel is formed on the furrow, respectively;
The prop is
The lower part is buried in the furrow, the hollow is formed inside the pillar portion is formed in the underground portion to form the inlet to allow the cold air flows into the hollow from the ground, and the upper portion of the pillar portion is formed in a pair spaced apart It includes a receiving plate is formed in the plate shape a plurality of fastening holes along the rim,
The cancer,
Insert plate in the center, and a pair of branch pipes protruding in both directions from the insert plate and each end is composed of a solar panel,
The insertion plate is interposed between the pair of receiving plate and has a circular cross section and a plurality of through holes are formed in a position opposite to the fastening hole, the branch pipe is formed in the hollow communicating with the hollow of the pillar portion therein Discharge holes are formed at the end of each branch pipe and the cold air flowing from the column part is discharged to the back surface of each solar panel through the discharge holes,
A first opening is formed between the receiving plate at the upper end of the pillar, and the insertion plate has a space formed therein, and a second opening communicating with the hollow of the branch pipe at both sides and communicating with the first opening at the bottom is formed. When the air temperature inside the pillar and the branch pipe rises, convection occurs and as the internal air flows out into the discharge hole, a negative pressure is formed in the hollow of the pillar and the branch pipe, and the ground air is naturally sucked into the inlet by the negative pressure. The cold air is continuously discharged to the discharge hole through the hollow of the pillar and branch pipe,
Farming photovoltaic device characterized in that the fixing bar is configured to pass through the fastening hole and the through hole facing each other so that the arm is fixed while the inclined gradient is formed in the support.
The method of claim 1,
The arm is a solar photovoltaic device characterized in that the height is configured to be adjusted in the holding. delete delete delete delete delete

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