KR100991237B1 - Solar power pagora - Google Patents

Abstract

The present invention relates to a solar power pagora having a sunshade function and capable of solar power generation. In particular the invention provides at least one strut; A solar power module positioned on an upper side of the support and coupled to the support so as to serve as a sunshade and convert solar energy into electric energy; By presenting a solar power pagora comprising a; power generation unit for generating the electrical energy converted by the solar power module, the sunshade effect and solar power generation efficiency can be maximized.

Pagora, Sunshade, Solar Power, Meeting

Description

PERGOLA HAVING SOLAR POWER GENERATOR}

The present invention relates to a solar power pagora having a sunshade function and capable of solar power generation.

As shown in Figure 1 and 2, in general, the pagora erected the support (10) and the roof 20 on the support 10, the structure to cover the sunlight to create the shade necessary for rest and rain, snow, hail This is to avoid the back.

By the way, as described above, although it is very beneficial to provide convenience for taking a break or the like, there are points to be improved as follows.

That is, the sun altitude changes according to the time of day, but since the roof 20 is fixed, the shade angle cannot be changed in response to the changing sun altitude, as shown by the arrows in FIG. As a result, there is a problem that cannot be prevented until sunlight enters sideways.

The present invention has been made in order to solve the above problems, and the object of the present invention is to provide a solar power pagora that can be combined with solar power while improving the sunshade angle can be adjusted.

The present invention to solve the above problems is at least one pillar; A solar power module positioned on an upper side of the support and coupled to the support so as to serve as a sunshade and convert solar energy into electric energy; It proposes a solar power pagora comprising a; power generation unit for generating electrical energy converted by the solar power module.

The solar power module preferably includes a solar cell for converting sunlight into electrical energy.

The solar power generation module is coupled to the rotatable frame; It is preferable to include; at least one solar power plate installed on the upper side of the frame.

The rotation center of the solar power module is preferably eccentric.

It is preferable to further include a rotation driving unit for automatically rotating the solar power module.

At least one hydraulic cylinder configured to rotate the solar power module while the rotation driving unit is adjusted in length by hydraulic pressure; It is preferable to include a hydraulic pressure control unit for controlling the hydraulic force of the hydraulic cylinder.

Preferably, the hydraulic cylinder is coupled to the bottom of the solar power module and the other end is coupled to the support so that the hydraulic cylinder is installed under the solar power module.

The hydraulic cylinder is preferably coupled to the edge side of the solar power module.

The rotation driving unit may further include at least one support that supports the solar power module and is adjustable in length as the solar power module is rotated.

It is preferable that one end is coupled to the bottom of the solar power module and the other end is coupled to the support so that the support is installed under the solar power module.

The support includes a first rod coupled to the solar power module; A second rod fitted to the first rod so as to be slidable and coupled to the post; And a rod elastic member installed on any one of the first rod and the second rod and supporting the other rod by an elastic force along the longitudinal direction of the support.

Preferably, one of the first rod and the second rod is formed with a long hole along the length of the support, and the rest of the first rod and the second rod is formed with a pin fitted to the long hole to be moved along the long hole.

According to the present invention, a solar power generation module is configured instead of a roof, so that solar power generation is combined with a sunshade function.

In addition, since the solar power module can be rotated, by adjusting the rotation angle of the solar power module in response to the solar altitude, it is possible to maximize the sunshade effect and solar power efficiency.

In addition, by maximizing the rotation angle range of the solar power module, the sun shade effect and solar power generation efficiency can be maximized in response to the solar altitude.

In addition, the shadow of the solar power generation module is not generated, thereby maximizing the solar power generation efficiency.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown below in FIG. 2, the solar power pagora according to the present invention is located at the upper side of the support 100 in order to convert solar energy into electrical energy while serving as a sunshade and at least one support 100. And a solar power generation module 200 coupled to the support 100 and rotatable, and a power generation unit 250 for generating electrical energy converted by the solar power generation module 200.

That is, when considering the aspect that the pagora also combines solar power generation, the solar power module is geographically suitable in that the pagora is installed to cover the sunlight in the sunny area, the solar module 200 is shaded Since it serves as a roof for the role, since interference elements such as obstacles that may cause shadows on the solar power generation module 200 may be excluded, the solar power generation efficiency may be maximized.

In addition, the solar power generation module 200 is formed wide and thin in order to obtain a lot of solar energy, it is possible to obtain the effect that the solar power generation module 200 can act as a shade without having to configure a separate roof for sunshade. have.

In particular, since the solar power generation module 200 can be rotated, the solar power generation module 200 can be rotated by chasing sunlight as the solar altitude changes depending on the time of day, and the rotation angle is adjusted in response to the solar altitude. By doing so, the sunshade effect and the solar power generation efficiency can be maximized.

Looking at a more specific embodiment of the present solar power pagora as follows.

Solar power is largely divided into solar thermal power generating heat energy or electrical energy for cooling and heating using solar heat, and solar power power converting solar energy into electrical energy. In the present embodiment, only the photovoltaic power generation suitable for supplying electricity such as the solar power pagora and the surrounding lighting or the lake pump will be described.

That is, the solar power generation module 200 includes a frame 210 coupled to the support pillar 100 so as to be rotatable, and at least one solar power generation plate 220 installed on the upper side of the frame 210, in particular, solar power generation. The plate 220 may be configured as a solar cell that generates an electromotive current by sunlight for photovoltaic power generation.

Frame 210 may be configured in a variety of structures, as a preferred example, as shown in the base plate 212 (base plate) for supporting the solar panel 220, and the solar module 200 is a support ( Protrudingly formed on the bottom surface of the base plate 212 so as to be rotatable with the 100 and comprises at least one rib 214 (lib) hinged by the support 100 and the hinge pin (P), etc. Can be.

Since the solar power module 200 is installed so that its center of rotation 200A is eccentric, it is preferable to maximize the principle of the lever to make the rotation angle range as large as possible. That is, when the rotation angle range of the solar power generation module 200 is wide, the rotation angle of the solar power generation module 200 can be optimized in response to the solar altitude, and the sunshade effect and solar power generation efficiency can be maximized.

Furthermore, the solar power pagora may further include a rotation driving unit 300 which automatically rotates the solar power module 200 so that the solar power module 200 can be more easily rotated.

The rotation driving unit 300 may be implemented by any driving force method such as power of the motor, air pressure, hydraulic force, electric power, combustion force, and the like.

 That is, the rotation driving unit 300 is at least one hydraulic cylinder 310 to rotate the solar power module 200 while the length is adjusted by the hydraulic force, and the hydraulic control unit 320 for controlling the hydraulic force of the hydraulic cylinder (310). It may be configured to include).

In particular, the hydraulic cylinder 310, one end is preferably coupled to the bottom surface of the solar power module 200 and the other end is coupled to the support 100 so that it is installed under the solar power generation module 200. That is, since there is no fear of shading on the solar panel 220 due to the hydraulic cylinder 310, the solar power generation efficiency can be maximized.

The hydraulic cylinder 310 is a solar power generation module 200 or so that the rotation of the solar power generation module 200 is not restricted by the coupling structure between the hydraulic cylinder 310, the solar power generation module 200, and the support 100. At least one of the solar power generation module 200 and the support 100 and the hinge module 500 may be hinged so as to be rotatable with respect to the support 100, respectively.

In addition, the hydraulic cylinder 310 is coupled to the edge of the solar power generation module 200 without being coupled to the inside of the solar power generation module 200 so that the rotation angle range of the solar power generation module 200 can be maximized as described above. To maximize the principle of the lever, the rotation angle range of the solar power module 200 can be as large as possible.

Hydraulic control unit 320, the hydraulic tank in which the hydraulic pressure supplied to the hydraulic cylinder 310 is stored, and the hydraulic pressure is selectively supplied from the hydraulic tank to the hydraulic cylinder 310 or the hydraulic pressure of the hydraulic cylinder 310 to be partially recovered In order to control the hydraulic pressure of the hydraulic cylinder 310, it may be configured to include a hydraulic control panel composed of a valve, a microcomputer and the like.

In addition, the rotation driving unit 300 supports the solar power generation module 200, and further includes at least one support 330 whose length is adjustable as the solar power generation module 200 is rotated, thereby providing a solar power generation module 200. This can be supported more robustly and stably.

In a specific embodiment of the support 330, in particular, referring to FIG. 7, the first rod 332 coupled with the solar power generation module 200, and the first rod 332 and the support 330 slide along the longitudinal direction. The first rod 332 and the second rod 334 to be fitted and coupled to the support 100, and the length of the support 330 adjusted as the solar module 200 is rotated to be maintained. It may be configured to include a rod elastic member 336 is installed on any one of the second rod 334 to support the other by the elastic force along the longitudinal direction of the support 330.

Thus, the length of the support 330 is maintained by the elastic force of the rod elastic member 336, so that the solar module 200 can be freely rotated without being constrained by the support 330, and also the rod elastic member 336 By maintaining the length to be adjusted of the support 330 by the elastic force of the support 330 can support the solar power module 200 is robust and stable.

Furthermore, in order to prevent separation of the first rod 332 and the second rod 334, any one of the first rod 332 and the second rod 334 may adjust the length of the support 330. A long hole 334A is formed along the length of 330, and the rest of the pin 332A may be formed to fit into the long hole 334A so as to move along the long hole 334A.

Of course, the support 330 is not limited to this embodiment, and any structure may be used as long as the structure is adjustable in length.

The support 330 is also the same as the rotation driving unit 300 described above, so that the shade is not formed on the solar panel 220 due to the support 330, one end is installed so that the solar power generation module 200 under It is preferable that the bottom surface of the module 200 is coupled and the other end is coupled with the support 100.

In addition, the support 330 may be installed along the height of the support 100, so as to support the solar power module 200 more stably and reliably.

In addition, the support 330 is preferably coupled to the hinge by the hinge module 510 and at least one of the solar power generation module 200 and the support 100, like the above-described hydraulic cylinder (310).

The solar power pagora configured as described above is capable of both manual control by automatic switch operation and automatic control according to the control logic previously input to the hydraulic control panel. However, manual control is difficult to optimize the rotation angle of the solar power module 200 in response to the solar altitude, and the inconvenience of having to adjust the rotation angle of the solar power module 200 several times a day, this solar power wave called It is desirable to automatically control the sunshade effect and maximize the solar power efficiency, convenience.

In particular, since the change in the solar altitude is different depending on the season and geographic location, and the amount of sunlight according to the weather conditions, in the case of automatic control, rather than adjusting the rotation angle of the solar power module 200 uniformly, the season, geographical It may be more preferable that the solar cell module 200 is programmed to be optimally rotated in consideration of location, weather, and the like. In this case, for more efficient automatic control, the hydraulic control unit and the generator 250 may be preferably organically linked to each other.

That is, as shown in FIGS. 9 and 10, as the length of the hydraulic cylinder 310 is changed by the hydraulic fluctuation of the hydraulic cylinder 310, the solar power generation module 200 is moved up and down about the center of rotation 200A. Rotating, and by adjusting the length of the support 330, the shade angle is optimized to correspond to the solar altitude, can always exhibit the shade effect, and the solar power angle is optimized to correspond to the solar altitude to maximize solar power efficiency Can be.

Since the above is merely described with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above All of the technical ideas together with the technical idea of the base will be included in the scope of the present invention.

1,2 is a view showing a pagora according to the prior art,

1 is a perspective view.

2 is a side view.

3 to 11 is a view showing a solar pagora according to the present invention,

3 is a front perspective view.

4 is a bottom perspective view.

5 is a front view.

6 is a side view.

7 is a schematic view of the support operation.

8 is a control block diagram.

9 and 10 are schematic views of angle adjustment.

<Explanation of symbols on main parts of the drawings>

100; Holding 200; Solar power module

210; Frame 220; Solar panels

250; Power generation unit 300; Revolving Drive

310; Hydraulic cylinder 320; Hydraulic control part

330; Support

Claims (12)

A solar power module positioned at an upper side of the support and coupled to the support so that the solar power can be converted into solar energy into the at least one support, and the solar energy is converted into electrical energy; A power generation unit for generating electric energy and a rotation driving unit for automatically rotating the solar power module; The rotation driving unit supports the solar power module and includes at least one support that is adjustable in length as the solar power module is rotated, The support is a solar power pagora characterized in that one end is coupled to the bottom surface of the solar power module and the other end is coupled to the support to be installed under the solar power module. The method according to claim 1, The solar power module is a solar power pagora comprising a solar cell for converting sunlight into electrical energy. The method according to claim 1, The solar power module A frame coupled to the prop so as to be rotatable; At least one solar power plate installed above the frame; Solar power pagora comprising a. The method according to claim 1, The solar power module is characterized in that the rotational center of the solar power module is eccentric. delete The method according to claim 1, The rotation drive unit At least one hydraulic cylinder configured to rotate the solar power module while being length-adjusted by hydraulic pressure; Solar power pagora comprising a hydraulic control unit for controlling the hydraulic force of the hydraulic cylinder. The method according to claim 6, The hydraulic cylinder The solar power pagora, characterized in that one end is coupled to the bottom surface of the solar power module and the other end is coupled to the support so that it is installed below the solar power module. The method of claim 7, The hydraulic cylinder Solar power pagora, characterized in that coupled to the edge side of the solar module. delete delete The method according to claim 1, The support is A first rod coupled with the solar power module; A second rod fitted to the first rod so as to be slidable and coupled to the post; A rod elastic member installed on any one of the first rod and the second rod and supporting the other rod by an elastic force along a longitudinal direction of the support; Solar power pagora comprising a. The method of claim 11, One of the first rod and the second rod is a long hole is formed along the length of the support, the rest of the solar power pagora characterized in that the pin is inserted into the long hole to be moved along the long hole is formed. .

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