KR102489653B1 - Expandable solar power generation apparatus - Google Patents

Abstract

The present invention relates to an expandable solar power generation device, which can easily expand a heat collection panel, comprising: a main frame; a subframe; a main heat collection panel; a support frame; a sub-heat collection panel; a pair of first rotation axes; a pair of second rotation axes; a pair of link plates; and a servo motor.

Description

Expandable solar power generation apparatus {Expandable solar power generation apparatus}

The present invention relates to an expandable photovoltaic power generation device, and more particularly, by simply rotating a part of a main heat collecting panel by a rotational force driven by a motor to overlap a part of the main heat collecting panel, and unfolding the heat collecting panel to the outside as necessary to make the heat collecting panel more visible. It relates to an expandable solar power generation device that can be expanded to further maximize solar power generation efficiency.

In general, solar thermal energy is easy to utilize compared to other energy sources, and power generation devices using solar thermal energy have recently been disclosed due to the usefulness of obtaining high-efficiency and abundant energy.

This photovoltaic power generation device includes a configuration that measures the altitude or direction of the sun or tracks sunlight according to a pre-programmed method according to time, collects solar energy through a heat collecting panel, and then converts it into electricity, there is.

The heat collecting panel is used to collect thermal energy from sunlight, and a plate-shaped panel having a relatively large area is used to collect a large amount of thermal energy.

Therefore, in order to change the angle of the heat collecting panel according to the altitude or direction of the sun, a rotating member is provided between the heat collecting panel and the support member to rotate the angle of the heat collecting panel. At this time, when the place where the heat collecting panel is installed is greatly affected by wind The rotating member may be damaged because it cannot withstand the wind pressure, and as a result, the heat collecting panel is also separated from the support member and damaged.

In the slide-type photovoltaic power generation device of Registered Patent No. 1166261 (July 10, 2012), a sub-collecting panel slides in and out of the hollow of the main heat-collecting panel of the heat-collecting panel, and an inclination adjusting means provided on the lower part of the heat-collecting panel. The angle of inclination of the heat collection panel is adjusted by a certain amount of power, and a rotation control means is formed to control the left and right rotation of the heat collection panel at the lower part of the tilt control means, and the heat collection panel, the tilt control means, and the rotation control means are formed as shafts. The support means is formed to support in the direction, and the heat collecting panel is controlled to face the sun by controlling the slide control means, the tilt control means, and the rotation control means so that the heat collecting area of the heat collecting panel can be changed.

Therefore, by making the area of the heat collecting panel that absorbs solar heat energy variable by a sliding method, the heat collecting panel is prevented from being damaged by wind pressure, etc., and a large amount of solar heat energy is absorbed by increasing the area of the heat collecting panel.

However, according to the prior art, a subframe coupled with a sub-heat collection panel is inserted into the main frame coupled with a main heat-collecting panel to enable withdrawal and withdrawal from the main frame by engagement of a driving gear and a rack gear. Since it is impossible to form a supporting means in the coupling structure, there is a problem in that it cannot be practically applied.

(Document 1) Registered Patent No. 1166261 (2012.07.10.)

Accordingly, the present invention is to solve the above problems, and the present invention is to provide sub heat collection panels at the upper part of the main heat collection panels on both sides or at the lower part by being spaced apart at a certain height, so that the sub heat collection panels are swing-rotated as necessary to obtain the main heat collection An object of the present invention is to provide an expandable photovoltaic device that can be extended to be flush with the panel.

An expandable photovoltaic device according to the present invention for achieving the above object is a main frame provided in the shape of a square frame, a bar-shaped sub-frame fixed at a predetermined interval on top of the main frame, and the sub-frame The main heat collecting panel arranged and fixed to the upper part of the main frame and the main heat collecting panel are provided as a support frame to form a certain inclination angle by spaced apart a certain length from the lower surface of the frame on both sides of the main frame so that the height of the rear side is higher than that of the front side. a sub heat collection panel positioned to cover the top or bottom of both sides or bottom of the main heat collection panel by a certain width; It protrudes from both ends of the subframe supporting the main heat collection panel to the front and rear ends of the main heat collection panel so as to be rotatably pivotally supported, and is formed in a pair shape spaced apart by a certain length to the outside on the same horizontal line a pair of first rotation shafts that are biased; A pair of heat collection panel frames supporting the lower part of the sub heat collection panel are rotatably supported by protruding from the front and rear ends of the heat collection panel frame from the front and rear ends of the heat collection panel frame supporting the lower portion of the sub heat collection panel, and are spaced apart at the same distance as the distance between the first rotation shafts. a pair of second rotation shafts formed in a shape and biased toward the opposite side of the first rotation shaft on the same horizontal line; A pair of link plates connected in parallel while mutually rotatable between ends of the first rotation shaft and the second rotation shaft so as to be eccentric in mutually opposite directions; It is shaft-coupled to one of a pair of first rotation shafts shaft-coupled to the sub-frame, fixed to the sub-frame or the main frame, and swings the sub-collecting panel by a rotational drive, and the sub-collecting panel This is a configuration composed of a combination of a servo motor to be able to extend from the main heat collecting panel.

When the sub heat collection panel is formed above the main heat collection panel, the first rotation shaft is formed below the sub frame, and the second rotation shaft is formed above the heat collection panel frame.

When the sub heat collection panel is formed below the main heat collection panel, the first rotation shaft is formed on the upper part of the sub frame, and the second rotation shaft is formed below the heat collection panel frame.

The pair of link plates are connected by a horizontal connection plate, and a piston end of a drive cylinder is connected to the connection plate, so that the sub heat collection panel swings by the driving of the drive cylinder while the sub heat collection panel It is made extensible from the main heat collection panel.

As in the configuration described above, by the expandable photovoltaic power generation device according to the present invention, the sub-collecting panels having a certain width provided on the upper or lower portions of both sides or lower portions of the main heat collecting panel are swinging so that both ends of the main heat collecting panel or By making it expandable from the bottom to the side or bottom, it is possible to easily expand the heat collection panel by a more simple operation.

1 is a front structural view of an expandable photovoltaic device according to the present invention
Figure 2 is a partially enlarged plan view of the expandable photovoltaic device according to the present invention
Figure 3 is a partially enlarged front view of the expandable photovoltaic device according to the present invention
4 is an enlarged plan view of a main part illustrating a configuration in which a swinging action of a sub heat collection panel is performed by a drive cylinder in an expandable photovoltaic device according to the present invention.
5 is a side view illustrating a state in which a sub heat collection panel of an expandable photovoltaic device according to the present invention operates.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention.

The scope of the present invention should not be construed as being limited by the embodiments described in the text.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the description of the embodiments, the same reference numerals are assigned to the same components, and descriptions of the same reference numerals are omitted in some cases.

1 is a front structural view of an expandable photovoltaic device according to the present invention, FIG. 2 is a partially enlarged plan view of an expandable photovoltaic device according to the present invention, and FIG. 3 is an expandable photovoltaic device according to the present invention. It is an enlarged front view of part of

As illustrated, the expandable photovoltaic device of the present invention includes a main frame 10, a sub frame 20, a main heat collecting panel 30, a support frame 40, a sub heat collecting panel 50, and a first rotating shaft ( 60), the second rotating shaft 70, and the servomotor 80.

In the present invention, the main frame 10, the sub frame 20, the main heat collection panel 30, and the support frame 40 are substantially the same as the previous configuration.

That is, the main frame 10 of the present invention is formed in the shape of a square frame, and the bar-shaped sub-frame 20 is fixedly connected to the main frame 10 by spaced apart from the upper surface at a predetermined interval.

In other words, the sub frame 20 is formed as a plurality of U-shaped or ㅁ-shaped bars formed on the upper surface of the main frame 10 equal to or longer than the horizontal length of the main frame 10 at regular intervals in the vertical direction. .

The main heat collection panel 30 is fixed to the upper portion of the plurality of subframes 20 .

The main heat collection panel 30 has a configuration in which panels of a certain size are arranged while making side surfaces contact each other.

The upper ends of the vertical support frames 40 are connected to the front and rear by a predetermined length from the bottom surfaces of the frames on both sides of the main frame 10 where the main heat collection panels 30 are installed by the subframe 20 .

At this time, the support frame 40 is formed so that the height of the rear support frame 40 is higher than that of the front, so that the main heat collecting panel 30 on the upper part of the support frame 40 has a predetermined inclination angle toward the front.

In such a configuration, sub heat collection panels 50 are formed on both sides or lower sides of the main heat collection panel 30 to cover the top or bottom with a certain width.

That is, the sub heat collection panel 50 has a structure in which a plurality of heat collection panels 51 provided with a certain width are fixed to a plurality of heat collection panel frames 52 at the bottom, and by such a sub heat collection panel 50, the main A certain width of both sides or the lower side of the heat collecting panel 30 is covered.

Therefore, the sub heat collection panel 50 is formed to have the same front and rear length or length between both ends of the main heat collection panel 30 so as to cover a predetermined width of the main heat collection panel 30 from the top or bottom.

At both end portions of the subframe 20 supporting the main heat collection panel 30, the pair of first rotary shafts 60 are rotatably supported on the same horizontal line by being eccentric to the outside and spaced apart by a predetermined length. do.

The pair of first rotational shafts 60 are pivotally supported by the sub frame 20 so that their ends protrude from the front and rear ends of the main heat collection panel 30 .

The heat collection panel frame 52 provided to support the lower portion of the sub heat collection panel 50 with respect to the first rotational shaft 60 formed on the surf frame 20 is eccentric to the rear side in correspondence with the sub frame 20, and The pair of second rotation shafts 70 are rotatably supported on the same horizontal line by spacing the same distance as the distance between the pair of first rotation shafts 60 .

However, the first rotation shaft 60 and the second rotation shaft 70 are formed at upper and lower positions corresponding to each other between the sub frame 20 and the heat collecting panel frame 52 .

In other words, in the configuration in which the sub heat collection panel 50 is formed above the main heat collection panel 30, the first rotation shaft 60 is formed below the sub frame 20, and the second rotation shaft 70 is formed at the bottom of the sub frame 20. Conversely, in a configuration in which the sub heat collection panel 50 is formed below the main heat collection panel 30 and formed on the upper part of the panel frame 52, the first rotating shaft 60 is formed on the upper part of the sub frame 20. It is more preferable that the second rotation shaft 70 is formed at the bottom of the heat collecting panel frame 52.

A pair of link plates 80 are connected in parallel between the front and rear ends of the first rotational shaft 60 and the second rotational shaft 70 thus formed.

That is, the first rotational shaft 60 and the second rotational shaft 70 provided as a pair are connected to each other as a link plate 80 between the left rotational shaft and the right rotational shaft, so that the pair of link plates 80 are provided in parallel. And, the ends of these link plates 80 are rotatably coupled to the first rotational shaft 60 and the second rotational shaft 70.

On the other hand, the servo motor 90 is connected to one side or both sides of the pair of first rotation shafts 60 supported by the sub frame 20 .

When the first rotational shaft 60 is rotated by the servomotor 90, the link plate 80 is rotated through the link plate 80 while the sub-thermal collection panel 50 is maintained in a horizontal state, so that the sub The heat collection panel 50 overlaps a part of the main heat collection panel 30 or is spread outward so that the heat collection panel expands.

However, the servomotor 90 of the present invention connects a pair of link plates 80 by a horizontal connection plate 81 as shown in FIG. 4, and the drive cylinder 100 is connected to the connection plate 81 The end of the piston is connected so that the sub heat collection panel 50 can be extended from the main heat collection panel 30 while the sub heat collection panel 50 swings by driving the drive cylinder 100 .

As described above, the actions and effects of the expandable photovoltaic device according to the present invention are described in more detail as follows.

In the present invention, sub heat collection panels 50 are provided with a certain width at the top or bottom of both ends of the main heat collection panel 30, so that these sub heat collection panels 50 are deployed outward by a swing operation as shown in FIG. It is characterized in that the heat collection panel 50 can be expanded as needed by enabling it to be.

To this end, the link plate 80 connects the heat collection panel frame 52 supporting the sub heat collection panel 50 and the sub frame 20 supporting the main heat collection panel 30 in parallel with each other, so that the link plate ( Even by the rotation of 80), the sub heat collection panel 50 maintains a horizontal state and allows the heat collection panel to extend beyond a certain width from both sides or lower ends of the main heat collection panel 50.

Therefore, normally, the sub heat collection panel 50 is located on the upper or lower part of both sides of the main heat collection panel 30. When the servomotor 100 or the drive cylinder is driven at a specific time period or when necessary, the sub heat collection panel 50 is developed on the same horizontal line as the main heat collection panel 30 so that solar power can be generated as much as the expanded area.

However, the sub heat collection pad 50 or a part of the main heat collection pad 30 whose upper part is covered by the sub heat collection pad 50 generates solar power only when the sub heat collection pad 50 is unfolded. Since the main heat collection pad 30 covered by the sub heat collection pad 50 or the sub heat collection pad 50 positioned below the main heat collection pad 30 does not receive sunlight, power generation is prevented. it is desirable

Since the amount of sunlight is most important for photovoltaic power generation, the amount of power generation can be maximized by deploying the sub heat collection panel 50 when the amount of sunlight is the strongest, and environmental reasons of the installation location such as near roads or railroads or climatic factors such as typhoons It has the advantage of being able to provide more effective power generation in places where it is not always possible to maintain an extended state by

As such, the present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, it should be said that such modifications or variations fall within the scope of the claims of the present invention.

10: main frame
20: sub frame
30: main heat collection panel
40: support frame
50: sub heat collecting panel
51: heat collection panel 52: heat collection panel frame
60: first rotation axis
70: second rotation axis
80: link plate
90: servo motor
100: drive cylinder

Claims (4)

The main frame 10 provided in the shape of a square frame and the bar-shaped sub-frame 20 fixed at a predetermined distance from the upper part of the main frame 10 and arranged and fixed to the upper part of the sub-frame 20 The main heat collection panel 30 and the bottom surface of both sides of the main frame 10 are separated by a certain length so that the height of the rear side is higher than the front side, so that the main heat collection panel 30 has a certain inclination angle. Support frame 40 ) In the configuration provided with,
a sub heat collection panel 50 formed of a heat collection panel 51 supported on an upper portion of the heat collection panel frame 52 while being positioned to cover the top or bottom of both sides or bottom of the main heat collection panel 30 by a certain width;
A pair of side ends of the subframe 20 supporting the main heat collection panel 30 protrudes from the front and rear ends from the main heat collection panel 30 so as to be rotatably pivotally supported and spaced apart by a certain length A pair of first rotation shafts 60 formed in a shape to be biased outward on the same horizontal line;
Both ends of the heat collection panel frame 52 of the sub heat collection panel 50 protrude beyond the sub heat collection panel 50 from the front and rear ends so as to be rotatably pivotally supported, and the distance between the first rotation shafts 60 and A pair of second rotational shafts 70 formed in a pair of shapes spaced at equal intervals and biased toward the opposite side of the first rotational shaft 60 on the same horizontal line;
A pair of link plates 80 connected in parallel while allowing mutual rotation between ends of the first rotational shaft 60 and the second rotational shaft 70 so as to be eccentric in opposite directions;
It is shaft-coupled to one of the pair of first rotation shafts 60 shaft-coupled to the sub-frame 20, and is fixed to the sub-frame 20 or the main frame 10 to rotate. a servomotor 90 for swinging the sub heat collection panel 50 by being driven so that the sub heat collection panel 50 is stacked on top of the main heat collection panel 30 or spread outward;
is made up of a combination of
When the sub heat collection panel 50 is stacked from the end of the main heat collection panel 30 to the top, the first rotating shaft 60 is formed on the lower part of the sub frame 20 supporting the main heat collection panel 30. and the second rotational shaft 70 is formed on the top of the heat collecting panel frame 52 so that the sub heat collecting panel 50 is spread to both sides by driving the servo motor 90 to maximize power generation. A scalable solar power plant that enables
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