KR20110041706A - High efficiency solar power generator of stack type - Google Patents

Abstract

PURPOSE: A laminated type solar power generator capable of generating high efficiency solar power per a unit is provided to delivery solar energy over a surface area between stacked solar panels. CONSTITUTION: A laminated type solar power generator comprises a transmitting plate(110), an optical member(120) and a solar panel(130). The transmitting plate has a cylindrical shape. Sunlight is transmitted to a hollow internal space through the transmitting plate. Optical members are arranged according to the side of the transmitting plate. Optical members diffuse the transmitted sunlight in the transmitting plate toward the internal space.

Description

High efficiency solar power generator of stack type

The present invention relates to a stacked high-efficiency photovoltaic device, and more particularly, to a stacked high-efficiency photovoltaic device that can increase the efficiency of electricity production by arranging the solar panels in a stacked type.

A solar cell is a device that absorbs the light energy of sunlight and converts it into electrical energy. In general, the solar panel is manufactured in a flat form and installed for a large area, which requires a lot of manufacturing cost and manpower and complicated installation.

In addition, solar panels usually produce 1 to 3 mW of solar electricity per square meter. At this time, only about 8 to 34% of the sunlight incident on the solar panel is recovered, and the remaining 92 to 66% is reflected again during the incident process and diverges to the atmosphere. Accordingly, the conventional solar panel has a problem that the recovery rate of sunlight is low and the efficiency of electricity production is low.

SUMMARY OF THE INVENTION An object of the present invention is to provide a stacked high efficiency photovoltaic device that produces a high efficiency electricity per unit area by arranging a plurality of solar panels in a stacked type.

The present invention has a hollow cylindrical shape, a plurality of transmission plates through which sunlight is transmitted into the hollow internal space, and a plurality of transmission plates are disposed along a surface of the transmission plate, and the sunlight transmitted through the transmission plates is Stacked high efficiency including optical means for scattering to the inner space side, and a plurality of solar cells are stacked spaced up and down in the inner space of the transmission plate, absorbing sunlight scattered by the optical means to produce electricity It provides a photovoltaic device.

In addition, the transmissive plate may have a polygonal cross section as the side surfaces of the plurality of transparent plates are connected to each other. In addition, the transmissive plate may be surface treated so that sunlight transmitted to the internal space does not leak to the outside.

Here, the transmissive plate, as the surface treatment, the high reflection film may be coated on the surface of the transmissive plate. In addition, the permeable plate may have an uneven structure formed on the surface of the permeable plate as the surface treatment.

The transmission plate may include an external tempered glass plate on which the surface treatment is performed, and an internal tempered glass plate on which the optical means are disposed and bonded in parallel with the external tempered glass plate.

In addition, the solar panel, the upper solar panel and the lower solar panel to produce electricity by absorbing the scattered sunlight from the upper and lower surfaces, respectively, so as to produce electricity on both sides, and the upper solar panel and the lower solar panel Is disposed between, may include a cooling means for cooling the solar panel.

The optical means may be a concave lens or a prism for scattering light.

According to the stacked high efficiency solar power generating device according to the present invention, the solar light transmitted to the interior space of the transmission plate is scattered to the entire area of the interior space through the optical means and evenly transmitted to the surface and between the stacked solar panels. There is an advantage that high electricity production efficiency per unit area can be obtained.

In addition, when surface treatment (high reflective film coating or uneven structure formation) is performed on the surface of the transmission plate, it is possible to recover the solar light that is going to the outside from the inner space again to the inside, and is transmitted to the solar cell panel. The amount of sunlight can be maximized.

Furthermore, when the cooling means is provided inside the solar panel, the solar panel can be maintained at a temperature at which maximum efficiency occurs, thereby preventing malfunction due to overheating and maximizing electricity production efficiency.

1 is a perspective view of a stacked high efficiency solar power generation apparatus according to an embodiment of the present invention. Referring to FIG. 1, the stacked high efficiency photovoltaic device 100 includes a transmission plate 110, a plurality of optical means 120, and a plurality of solar panels 130.

The transmission plate 110 has a hollow cylindrical shape, and sunlight is transmitted to the hollow inner space 10. The transmissive plate 110 has a polygonal cross section as the side surfaces of the plurality of transparent plates 110a are connected to each other.

Increasing the number of the transparent plate members 110a may form a transmissive plate 110 having a circular cross section. In addition, as the number of the transparent plate members 110a increases, the transmission efficiency of solar light may be increased in the outer circumferential direction of the transparent plate 110.

In the case of FIG. 1, the transmissive plate 110 having an octagonal cross section is illustrated using a total of eight transparent plate materials 110a. Of course, the illustration of the four transparent plate front of the front in Figure 1 for convenience of explanation.

The transparent plate 110a is a material such as transparent tempered glass, reinforced acrylic is used. The power generator 100 is usually installed outdoors. Therefore, when there is no separate external protection means, the transmissive plate 110 is a tempered glass material is more suitable than the reinforced acrylic material in consideration of toughness against external impact.

The optical means 120 is disposed in plural along the entire surface of the transmissive plate 110 and serves to scatter the sunlight transmitted through the transmissive plate 110 toward the inner space 10. That is, the optical means 120 scatters the transmitted sunlight in multiple directions so that the sunlight reaches the entire region of the internal space 10.

These optical means 120 is a concept encompassing an optical device for scattering light. For example, the optical means 120 means a concave lens, a prism (ex, trapezoidal shape) or the like. Here, in addition to the trapezoidal shape, the prism may have various shapes for scattering light.

The solar panels 130 are stacked and spaced apart from each other in the inner space 10 of the transmission plate 110. The solar panels 130 absorb electricity from the scattered light from the optical means 120 to produce electricity.

Sufficient sunlight is present in the internal space 10 by the optical means 120, and the sunlight is transmitted between the solar panels 130 arranged in a stack, and thus, high per unit area. Electric production efficiency can be obtained. Here, it is apparent that as the number of stacked layers of the solar cell panel 130 is increased, the electricity production efficiency is increased.

For example, the thickness of the solar panel 130 may be 5 ~ 7cm, the vertical separation interval of the solar panels 130 may be 10cm. If a total of 10 solar panels 130 are stacked, the height of the photovoltaic device 100 is about 140 ~ 160cm.

The conventional solar cell panel is spread out in the form of a plate and extends, requiring a large area and increasing installation costs. On the contrary, since the stacked high efficiency solar power generator 100 has a structure in which the solar panels 130 are stacked up and down, a larger number of solar panels 130 can be arranged in the same area, thereby providing high efficiency. Electricity production becomes possible.

Furthermore, as the transmission plate 110 formed of tempered glass material has a polygonal pillar shape, even when sunlight is incident in one direction, sunlight may propagate and scatter in the entire direction in the inner space 10. have. Therefore, unlike the conventional solar panel, there is an advantage that does not need to consider the direction in which sunlight is incident. In addition, the stacked high-efficiency photovoltaic device 100 can be produced in a factory in the form of a finished product, receiving fewer installation spaces and space, there is an advantage that it is easy to install and use.

FIG. 2 is a cross-sectional view of the solar panel shown in FIG. 1. Referring to FIG. 2, the solar panel 130 includes an upper solar panel 131 and a lower solar panel 132 to produce electricity on both sides. That is, the upper solar panel 131 and the lower solar panel 132, the solar light scattered through the optical means 120 is absorbed from the upper and lower surfaces, respectively to produce electricity.

Here, as the cooling means 133 is disposed between the upper solar panel 131 and the lower solar panel 132, each of the solar panels 131 and 132 on both sides may be cooled. For example, the cooling means 133 cools the heated solar panels 131 and 132 by flowing cooling water into the cooling tube 134. According to the cooling means 133, the solar cell panels 130 can be maintained at a temperature at which maximum efficiency occurs, thereby maximizing electricity production efficiency, and overheating of the solar cell panel 130 and Malfunction can be prevented.

In addition, the power generation device 100 includes a control box 140 on the outside. The control box 140 has a pump for flowing a cooling water for cooling the solar panel 130. The control box 140 may use a portion of the power generated from the solar panel 130 as a driving power of the pump, and the remaining power may be transmitted to the outside (eg, battery, electricity supplier, etc.).

3 is a cross-sectional view according to an embodiment of the transmitting plate shown in FIG. 1. The optical means 120, for example, has a structure that is inserted into the inner groove 112b portion of the inner surface of the transmission plate (110). Of course, the optical device 120 is disposed on the transmission plate 110 has a variety of modifications.

The transmissive plate 110 is surface treated to prevent leakage of sunlight transmitted to the internal space 10 to the outside. The surface treatment may be a form in which a high reflective film is coated on the surface of the transmissive plate 110, a form in which an uneven structure is formed on the surface of the transmissive plate 110, and the like. The uneven structure is to add the effect of the rough surface on the surface of the transmission plate (110). Here, the surface treatment is performed on one or both surfaces selected from the outer surface 111 and the inner surfaces 112a and 112b of the transmission plate 110.

According to the surface treatment, although it is possible to transmit the sunlight to the interior space 10 of the transmission plate 110, the sunlight to go out from the interior space 10 to the interior space 10 again It serves to reflect. That is, the transmissive plate 110 can confine sunlight to the inner space 10 of the transmissive plate 110 through the surface treatment.

In other words, the stacked high-efficiency photovoltaic device 100 transmits solar light transmitted to the inner space 10 of the transmission plate 110 to the entire region of the inner space 10 through the optical means 120. At the same time as the scattering, the solar light that is going to the outside in the inner space 10 can be recovered again through the surface treatment performed on the transmission plate 110, the sun is delivered to the solar panel 130 The amount of light can be maximized.

4 is a cross-sectional view according to another embodiment of the transmitting plate shown in FIG. 1. Referring to FIG. 4, the transmission plate 200 includes an external tempered glass plate 211 and an internal tempered glass plate 212. The outer tempered glass plate 211 is subjected to the surface treatment to induce an internal reflection on the sunlight to go out.

The inner tempered glass plate 212 is bonded in parallel to the inner side of the outer tempered glass plate 211, the optical means 120 is disposed along the entire surface. Of course, the surface treatment of inducing the internal reflection may also be performed on the surface of the inner tempered glass plate 212.

For example, the transmission plate 200, the outer tempered glass plate 211 is coated with a high reflection film on the surface, and the inner tempered glass plate 212, the optical means 120 (ex, concave lens) is disposed It may be in the form of adhesive bonding to each other.

Although the present invention has been described with reference to the embodiments shown in the drawings, these are merely exemplary and those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

1 is a perspective view of a stacked high efficiency solar power generation device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of the solar panel shown in FIG. 1.

3 is a cross-sectional view according to an embodiment of the transmitting plate shown in FIG. 1.

4 is a cross-sectional view according to another embodiment of the transmitting plate shown in FIG. 1.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

100: stacked high efficiency photovoltaic device

110,210: transmission plate 110a: transparent plate

111: outer surface 112a, 112b: inner surface

120: optical means 130: solar panel

131: upper solar panel 132: lower solar panel

133: cooling means 134: cooling tube

140: control box 211: external tempered glass plate

212: internal tempered glass

Claims (8)

A transmissive plate having a hollow cylindrical shape and transmitting sunlight to the hollow internal space; A plurality of optical means disposed along a surface of the transmission plate and scattering sunlight transmitted through the transmission plate toward the inner space; And Laminated high efficiency photovoltaic device comprising a plurality of solar cells are stacked spaced apart vertically in the inner space of the transmission plate, and absorbs the sunlight scattered by the optical means to produce electricity. The method according to claim 1, The transmission plate, Stacked high efficiency photovoltaic device having a polygonal cross-section as the side of the plurality of transparent plate is formed connected to each other. The method according to claim 1 or 2, The transmission plate, Stacked high efficiency solar power generation apparatus is a surface treatment is performed so that the sunlight transmitted into the inner space does not leak to the outside. The method of claim 3, The transmission plate, The surface treatment method, a laminated high efficiency photovoltaic device in which a high reflection film is coated on the surface of the transmission plate. The method of claim 3, The transmission plate, The laminated type high efficiency photovoltaic device in which the uneven structure is formed on the surface of the transmission plate as the surface treatment. The method of claim 3, The transmission plate, An external tempered glass plate on which the surface treatment is performed; And Laminated high-efficiency photovoltaic device comprising an inner tempered glass plate is disposed in the optical means and bonded in parallel with the outer tempered glass plate. The method according to claim 1, The solar panel, An upper solar panel and a lower solar panel for absorbing the scattered sunlight from the upper and lower surfaces to produce electricity so as to produce electricity on both sides; And Laminated high efficiency solar power generation device is disposed between the upper solar panel and the lower solar panel, comprising a cooling means for cooling the solar panel. The method according to claim 1, wherein the optical means, Stacked high efficiency photovoltaic device that is a concave lens or prism for scattering light.

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