KR101685178B1 - a Solar cell module with improved power generation efficiency - Google Patents

Abstract

The present invention relates to a solar cell module wherein a concentrating solar cell unit and a non-concentrating solar cell are installed in a composite way to generate power by solar light. According to an embodiment of the present invention, the solar cell module with improved power generation efficiency comprises: a non-concentrating solar cell of a rectangular shape whose corners are cut; a cell support panel on which the non-concentrating solar cells are arranged in a grid shape; a plurality of concentrating solar cell units installed in non-installation areas formed by gathering cut corner portions of the non-concentrating solar cells arranged in a grid shape on the cell support panel; and a concentration cover installed on an upper portion of the solar cell module and provided with a lens unit disposed on a portion where each concentrating solar cell unit is positioned to concentrate light on the concentrating solar cell units. Therefore, damage to the non-concentrating solar cells is prevented and the concentrating solar cell units are efficiently arranged to improve power generation efficiency.

Description

A solar cell module with improved power generation efficiency,

The present invention relates to a solar cell module in which a condensing type solar cell unit and a non-condensing type solar cell are installed in combination to generate solar light.

2. Description of the Related Art Generally, a solar cell is a device for generating sunlight. The solar cell is formed in a flat plate shape, and is composed of a non-condensing solar cell which generates solar light totally and a condensing type solar cell which is generated by sunlight condensed by a condenser such as a lens Batteries.

On the other hand, a plurality of non-condensing solar cells are arranged on a flat plate. However, in the condensing type solar cell, a condensing device capable of condensing light must be located in front of the power plant.

In order to solve this problem, a hybrid solar cell of Korean Patent Registration No. 10-1217540 (published on Feb. 13, 2013) has been disclosed.

A conventional hybrid solar cell is a hybrid solar cell which integrally includes a light-collecting solar cell and a non-condensing solar cell, and includes a plurality of non-condensing solar cells directly irradiated with sunlight to perform solar power generation; At least one condensing type solar cell for collecting sunlight to perform solar power generation; A light collecting unit collecting and supplying solar light to the at least one light-converging solar cell; And a solar tracking system for accurately focusing solar light incident through the light collecting unit on the condensing type solar cell, wherein the one or more condensing type solar cells are embedded in the non-condensing type solar cell, And a three-axis tracking system.

Such a conventional hybrid solar cell was installed in a form that the light-convergence type solar cell was buried in the non-light-convergence type solar cell, and the power generation efficiency was improved by performing both the convergence type and the non-light-convergence type solar cell.

However, in the conventional hybrid solar cell, since the non-condensing solar cell must be cut in order to deposit the condensing solar cell in the non-condensing solar cell, not only the non-condensing solar cell is broken but also the non- There is a problem that the power generation efficiency of the non-light-converging type solar cell is lowered.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a light-condensing type solar cell which can prevent a decrease in power generation efficiency by installing a light- In addition, it is an object of the present invention to provide a solar cell module in which the light-condensing type solar cell and the non-condensing type solar cell are efficiently disposed and both of them simultaneously perform power generation, thereby improving power generation efficiency.

According to an aspect of the present invention, there is provided a solar cell module having improved power generation efficiency, comprising: a square-shaped non-condensing solar cell having a corner cut out; A plurality of light-collecting type solar cell units each provided for each non-built-up region in which cut-away corner portions of the non-condensing solar cell arranged in a lattice form in the cell support panel are gathered, And a condensing cover including a lens unit disposed on an upper portion of the unit and provided for each portion in which each condensing type solar cell unit is positioned so as to condense light into the condensing type solar cell unit.

The cell supporting panel is formed with through-hole concentrating photovoltaic cells in which the condensing type solar cell unit is seated, and a surface in the opposite direction of the condensing type solar cell unit, As shown in FIG.

The condensing type solar cell unit may include a thermocouple attached to the condensing type solar cell unit exposed at the rear surface of the cell supporting panel and generated by heat generated in the condensing type solar cell unit.

The thermocouple may include a heat sink for cooling the surface of the condensing type solar cell unit to generate a temperature difference on an opposite surface thereof.

The condensing cover may include a transmissive region through which the light is directly transmitted to the non-condensing solar cell in a remaining portion of the lens portion except for the lens portion.

And a spacing frame that adjusts a spacing distance of the condenser cover in the cell support panel so that the focal point of the lens unit matches the condensing type solar cell unit.

The cover may include a cover having a wide upper end and a narrower end toward the lower end to prevent the light condensing cover from being deformed by solar heat by supporting the condensing cover in the condensing type solar cell unit.

According to the present invention, a light collecting type solar cell unit is provided for each space between empty spaces of non-condensing solar cell units provided on a cell supporting panel, and both are installed without damaging the non-condensing solar cell, .

In addition, the lens cover for collecting sunlight and the transmission area for transmitting sunlight are divided into a transparent cover and a condensing solar cell unit and a non-condensing solar cell can simultaneously generate electricity, and the solar light transmitted through the lens unit It is possible to improve the power generation efficiency by performing the power generation in the non-condensing solar cell of sunlight scattering among the irregularly reflected solar cells.

In addition, the light-convergence type solar cell unit can be provided with a thermocouple to perform power generation according to the temperature difference between both sides, thereby improving the power generation efficiency.

Further, even if the focus lens is provided in the light-convergence type solar cell unit and the focus of the lens part of the light-collecting cover does not exactly coincide with the light-convergence type solar cell unit, the focus lens accurately provides solar light to the light- .

Further, the spacing frame is provided to adjust the height of the condensing cover, so that the focus of the condensing cover can be easily adjusted.

In addition, the light-collecting cover can be supported by the cover-supporting member to prevent the lens unit from being tilted in accordance with the deformation of the light-collecting cover.

1 is a perspective view illustrating a solar cell module with improved power generation efficiency according to an embodiment of the present invention.
2 is a cross-sectional side view of a solar cell module with improved power generation efficiency according to an embodiment of the present invention, which is cut in a diagonal direction.
3 is a plan view showing a cell supporting plate of a solar cell module with improved power generation efficiency according to an embodiment of the present invention.
4 is a side cross-sectional view illustrating a light-concentrating solar cell unit of a solar cell module with improved power generation efficiency according to an embodiment of the present invention.
5 is a plan view showing a light-collecting cover of a solar cell module with improved power generation efficiency according to an embodiment of the present invention.
6 is a side sectional view cut along the diagonal direction showing a solar cell module with improved power generation efficiency according to an embodiment of the present invention, and shows a solar light inflow path.
FIG. 7 is a side cross-sectional view of a solar cell module with improved power generation efficiency according to an embodiment of the present invention, showing a state in which a cover is provided. FIG.

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

1 to 3, a solar cell module 100 having improved power generation efficiency according to an embodiment of the present invention may include a non-condensing solar cell 120. [

The non-condensing solar cell 120 can convert solar light energy into electrical energy.

Meanwhile, the non-coherent solar cell can perform power generation by converting the light energy into electric energy by the potential difference between the P-type semiconductor and the N-type semiconductor, or may be realized by a semiconductor made of an organic compound or silicon .

In addition, the non-condensing solar cell 120 may be formed in a flat plate shape so as to generate power by receiving solar light over the entire area.

In addition, the non-condensing solar cell 120 may have a shape in which four corners are cut out in a diagonal or curved shape in a rectangular shape.

Here, the non-condensing solar cell 120 is manufactured in the form of a circular semiconductor wafer. In the case where the non-condensing solar cell 120 is circular, since it takes up a lot of installation space, And are cut out in a rectangular shape.

On the other hand, when the semiconductor wafer is cut into a quadrangular shape, the area of the semiconductor wafer is used as much as possible because of a large number of cut parts. In order to minimize the installation space, May be manufactured in a form of cutting.

Since the non-condensing type solar battery cell manufactured by cutting the circular semiconductor wafer in this manner is manufactured in a quadrangular shape in which four corners are cut out, the installation space is minimized and the circular semiconductor wafer is cut to minimize the discarded portion .

1 to 3, a solar cell module 100 having improved power generation efficiency according to an embodiment of the present invention may include a cell supporting panel 130. [

The cell supporting panel 130 may be formed in the form of a rectangular plate, and a plurality of non-condensing solar cells 120 may be arranged in a lattice form.

The non-condensing solar cell 120 provided on the cell supporting panel 130 is mounted on the upper surface of the cell supporting panel 130 or on the upper surface of the cell supporting panel 130, The light collecting type solar cell 120 may be inserted into the collective photovoltaic cell entrance hole 133 and the collective photovoltaic cell 120 may be inserted into the collective solar cell 120, The battery cells 120 are electrically connected to each other to collect electricity generated in one place.

The cell supporting panel 130 may be provided with a condensing type solar cell unit 140 to be described later. The details of the installation of the condensing type solar cell unit 140 will be described together with the following description of the condensing type solar cell unit 140.

1 to 4, a solar cell module 100 having improved power generation efficiency according to an embodiment of the present invention may include a light-collecting type solar cell unit 140.

The condensing type solar cell unit 140 can convert light energy into electric energy by a potential difference, and can convert sunlight into condensed light energy into electric energy.

The condensing type solar cell unit 140 includes a condensing solar cell element 141 manufactured by bonding different kinds of compounds and a substrate 142 on which the condensing solar cell element 141 is mounted and a condensing solar cell element 141 And a heat sink 143 attached to the rear surface of the substrate 142 on which the heat sink 143 is mounted to dissipate heat generated in the light collecting solar cell element 141.

Here, in the embodiment, the heat sink 143 is shown as a plurality of heat radiating fins standing up, but may be formed to have various shapes or structures capable of performing heat radiation.

Further, the heat sink 143 may not be provided for each light-condensing solar cell unit 140, but may be constructed so that a plurality of light-collecting solar cell units 140 are brought into contact with each other by a single large heat sink.

The light collecting type solar cell unit 140 is arranged in a lattice form in the cell supporting panel 130 and is provided with a non-assembled solar cell 120, ).

At this time, the light-condensing type solar cell unit 140 is inserted into the collective photovoltaic cell deep hole 133 passing through the cell supporting panel 130 so that the heat sink 143 is exposed to the rear of the cell- Or the like.

The condensing type solar cell unit 140 includes a plurality of condensing type solar cell units 140 electrically connected to each other or electrically connected together with the non-condensing type solar cell 120 to collect the generated electricity into one place .

Although the substrate 142 of the light-convergence type solar cell unit 140 is shown as a square in the drawing, the substrate 142 is formed in a circular shape, the outer peripheral surface thereof is threaded, The photovoltaic solar cell unit 140 of the photovoltaic cell 130 is formed in a circular shape and has a screw thread corresponding to the thread formed around the substrate 142 so that the photovoltaic cell unit 140 is connected to the photovoltaic cell inside hole 133 And can be coupled in a screwed manner.

Meanwhile, the light-collecting type solar cell unit 140 may include a thermocouple 147.

The thermocouple 147 can generate electricity by the heat generated in the light-condensing type solar cell unit 140 and the temperature difference between the outside.

On the other hand, the thermocouple 147 can be implemented by a thermoelectric element that develops by a seeback effect.

The heat sink 143 is provided on the opposite surface of the thermocouple 147 to be attached to the light-convergence type solar cell unit 140 to increase the amount of generated electricity by enlarging the temperature difference on both sides.

One side of the thermocouple 147 is heated by the condensing type solar cell unit 140 while the other side is cooled by the heat sink 143 and the heat sink 143 is heated by the sunlight on the cell supporting panel 130 The temperature difference between both surfaces of the thermocouple 147 is greatly generated, so that the thermocouple 147 can be generated.

On the other hand, the thermocouple 147 may be electrically connected to the light-collecting solar cell unit 140 or the non-light-converging solar cell 120, or both, to provide electricity generated through the one place.

Further, the condensing type solar cell unit 140 may include a focusing lens 145.

The focus lens 145 may collect the light radiated from the outside to provide a light collecting solar cell element 141 and focus the light of the focus lens 145 to be located at the center of the light collecting solar cell element 141 And may be installed in the light collecting type solar cell unit 140.

On the other hand, the focal lens 145 is formed to have a convex curved surface at an upper portion, and the opposite direction to a curved surface can be formed to have a flat surface. The focal lens 145 may be installed on the substrate 142 by a lens support 144.

The lens support 144 is coupled to the substrate 142 in a screwed manner such that the screw rod supporting the focus lens 145 is screwed into the lens 145 to support the focusing lens 145 on the focusing solar cell element 141, And adjust the position of the focus according to the type or size of the focus lens 145. [0064]

1, 2, and 5, a solar cell module 100 having improved power generation efficiency according to an embodiment of the present invention may include a light-collecting cover 110. FIG.

The condenser cover 110 is positioned above the cell support panel 130 to collect the light generated from the sun and provide it to the condensing type solar cell unit 140.

Meanwhile, the light-collecting cover 110 may be formed only of the lens unit 111, or may include the lens unit 111 and the transmissive area 113.

The lens unit 111 may collect solar light and provide the solar cell unit 140 with the condensing type solar cell unit 140. The condensing type solar cell unit 140 may be installed in the condensing cover 110.

The lens unit 111 may be formed in a circular shape having a maximum radius so that the lens units 111 provided at positions corresponding to the respective condensing type solar cell units 140 do not overlap with each other. 111 may be configured to focus on the light-collecting type solar cell unit 140 corresponding to each lens unit 111.

The lens unit 111 may be embodied such that a concave and a convex pattern formed in a plurality of concentric circles on the plurality of concentric circles such as a flannel lens is formed so that sunlight is collected at the center, And may be installed in the condensing cover 110 in the form of a lens.

The transmissive region 113 is formed in a portion of the condensing cover 110 so that the light is transmitted through the lens portion 111 without being converged by the lens portion 111 and is provided to the non-condensing solar cell 120, May be formed in a transparent manner.

Here, the light-collecting cover 110 is formed by forming a transmissive region 113 having a uniform pattern around the periphery of the lens portion 111 in a pronelel lens having a single lens portion 111, Or may be configured such that they are connected to each other by the size of the panel 130 or may be configured to be supported by a frame so that each of the condenser covers 110 is connected to each other.

Even if the focal point of the lens unit 111 does not exactly coincide with the condensing type solar cell unit 140, if the focal lens 145 is incident only on the focal lens 145, It can be accurately incident on the battery unit.

As shown in FIGS. 1 and 2, the solar cell module 100 with improved power generation efficiency according to the embodiment of the present invention may include a spacing frame 150.

The spacing frame 150 can support the light collecting cover 110 in the cell supporting panel 130 so that the focal point of the lens unit 111 coincides with the light collecting type solar cell unit 140.

The spacing frame 150 may be provided to seal the side surface of the cell supporting panel 130 and the spacing frame 150 to prevent foreign matter from entering the cell supporting panel 130. Alternatively, A plurality of bars may be provided around the cell supporting panel 130 to separate the light collecting cover 110 from each other.

The spacing frame 150 may include a cover frame 151 that supports the condenser cover 110 and a panel frame 153 that is installed on the cell support panel 130.

The cover frame 151 is formed so as to surround the side surface of the condenser cover 110. The panel frame 153 is disposed so as to surround the side surface of the cell support panel 130,

The panel frame 153 and the cover frame 151 are provided with slide holes 156 in the form of elongated holes to be fastened to the slide holes 156 by fastening members 157 such as bolts and nuts. .

At this time, since the cover frame 151 of the panel frame 153 can be fixed by adjusting the height by the slide ball 156 in the form of a long hole, the height of the condenser cover 110 installed on the cover frame 151 can be changed The position of the focus of the lens unit 111 can be changed.

As shown in FIG. 7, the solar cell module with improved power generation efficiency according to the embodiment of the present invention may further include a cover member 160.

The cover member 160 is disposed on the light collecting cover 110 so that the focal point of the lens unit 111 of the light collecting cover 110 is positioned on the light collecting solar cell element 141 of the light collecting solar cell unit 140. [ And can be supported apart from the unit 140.

The cover member 160 may be provided for each light-collecting type solar cell unit 140 to prevent the light-collecting cover 110 from being deformed by solar heat or changing the focus of the lens unit 111 due to sagging And the cover member 160 may be configured such that the lens parts 111 of the light-collecting cover 111 are not integrally formed, but are installed separately for each cover member 160 in a separate form.

The cover piece 160 may be formed of a transparent material so that diffused sunlight can be transmitted through the lens part 111. The planar shape of the cover part 160 may be polygonal or circular, And the lower portion may be formed in a narrow funnel shape.

The cover member 160 may be formed so that its upper surface has a circumference corresponding to the lens portion 111 of the condensing cover and the lower portion has a circumference around which the condensing solar cell element 141 is inserted.

A coupling unit 161 may be formed at the lower end of the cover member 160 to be screwed on an inner circumference or an outer circumference of the cover unit 160. In the light condensing type solar cell unit 140, (149) are formed and screwed to each other.

When the light-convergence type solar cell unit 140 includes the focal lens 145, the focal lens 145 is not provided on the lens support 144 but on the inner peripheral lower end portion of the cover support 160 May be installed.

The operation and effects of the above-described respective structures will be described.

The solar cell module 100 having improved power generation efficiency according to the embodiment of the present invention includes a plurality of non-condensing solar cells 120 arranged in a lattice form on a cell supporting panel 130, The light-collecting type solar cell unit 140 is provided for each of the uncovered areas 135 where the corners of the battery cell are gathered.

In the embodiment, a solar cell is installed in a lattice form of 4 × 4, and a solar cell unit is installed for every corner where solar cells are gathered to provide a total of nine light-collecting solar cell units 140.

At this time, the light-collecting type solar cell unit 140 is installed in the form of being inserted into the collective photovoltaic cell hole 133 formed in the non-installed area 135, and the part where the heat sink 143, And is projected rearward.

A thermocouple 147 is provided between the condensing type solar cell unit 140 and the heat sink 143 to generate electricity by heat generation.

A light collecting cover 110 having a lens unit 111 for collecting light by the light collecting type solar cell unit 140 is spaced apart from the cell supporting panel 130, Is spaced apart from the cell support panel (130) by a spacing frame (150).

At this time, the light-collecting cover 110 is formed as a transmissive region 113 except for the lens portion 111 so that sunlight can flow directly into the non-light-collecting solar cell 120, And the cell support panel 130 is coupled to the panel frame 153 and interposed therebetween to adjust the height of the condenser cover 110 in the cell support panel 130 And are combined with each other to adjust the position of the focal point of the lens portion 111. [

In order to prevent the lens portion 111 of the condenser cover 110 from being deformed by the solar heat, the condenser lens 110 is supported by the condenser type solar cell unit 140 The cover supporting member 160 may be installed.

6, when the sunlight is incident through the condenser cover 110, the solar cell module 100 having improved power generation efficiency according to the embodiment of the present invention, as shown in FIG. 6, The sunlight incident through the unit 111 is gathered by the lens unit 111 to be provided as a focal point of the lens unit 111 and supplied to the condensing solar cell unit 140, To carry out the development.

At this time, if the focus of the lens portion 111 is provided to the focus lens 145 even if the focus of the lens portion 111 does not exactly coincide with the condensing solar cell element 141, the focus lens 145 again collects the sunlight into the condensed solar cell element 141 Provide development in the form provided.

On the other hand, when the light-converging solar cell element 141 develops heat, the generated heat is transmitted to the thermocouple 147 located on the rear side of the substrate 142, and by the temperature difference between both surfaces of the thermocouple 147 The thermocouple 147 also performs power generation.

At this time, the heat sink 143 is installed on the surface of the thermocouple 147 located opposite to the surface on which the light collecting solar cell element is located, and the heat sink 143 is disposed on the rear side of the cell- The temperature difference between the two surfaces of the thermocouple 147 is greatly increased and the amount of generated electricity can be increased.

The sunlight incident through the lens unit 111 of the condenser cover 110 passes through the lens unit 111 and is mostly gathered as a focal point but a part of the sunlight diffuses to the non-condensing solar cell 120 So that the non-condensing solar cell 120 can perform power generation.

Since the cover supporting unit 160 is formed as a transparent body even if the cover supporting unit 160 is installed in the sunlight incident on the lens unit 111 through the lens unit 111, And then transmitted to the non-light-converging solar cell 120.

The solar light transmitted to the transmission region 113 of the condenser cover 110 is directly supplied to the non-condensing solar cell 120 and can be generated by the non-condensing solar cell 120.

Therefore, in the solar cell module 100 having improved power generation efficiency according to the embodiment of the present invention, the light-collecting solar cell unit 140 and the non-light-converging solar cell 120 perform power generation together to improve power generation efficiency .

Further, by performing power generation in the non-condensing solar cell 120, not only the transmission region 113 of the condenser cover 110 but also the sunlight that is incident through the furnace portion of the condenser cover 110 and is diffusely reflected, Can be improved.

In addition, the light-collecting solar cell unit can be installed in a non-installation area where the non-light-converging solar cell 120 is not installed, and can be installed without damaging the non-light-converging solar cell 120. [

In addition, a thermocouple 147 is provided in the light-condensing type solar cell unit 140 heated by sunlight, and the power generation is performed by the temperature difference between the inside and the outside, so that the power generation efficiency can be improved.

Further, even if the focus lens 145 is provided on the condensing type solar cell unit 140 so that the focus of the lens part 111 does not exactly coincide with the condensing type solar cell unit 140, By concentrating solar light on the unit 140, power generation efficiency can be improved.

Also, it is possible to prevent the focusing cover 160 from being distorted by the solar heat due to the condensing cover 110, and the focusing of the lens unit 111 can be prevented.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And all changes and modifications to the scope of the invention.

100: solar cell module with improved power generation efficiency 110: condenser cover
111: Lens portion 113: Transmission region
120: non-condensing solar cell 130: cell supporting panel
131: Photovoltaic power plant construction 133: Photovoltaic power plant construction
135: uncovered area 140: condensing type solar cell unit
141: Condenser solar cell element 142: substrate
143: heat sink 144: lens support
145: Focus lens 147: Thermocouple
150: spacing frame 151: cover frame
153: Panel frame 155: Slide ball
157: fastening member 160: cover-
161:

Claims (7)

A square type non-condensing solar cell having a corner cut out,
A cell supporting panel in which the non-condensing solar cells are arranged in a lattice form,
A plurality of light-collecting type solar cell units provided for each non-built-up region in which cut-away corner portions of the non-condensing solar cell arranged in a lattice form in the cell supporting panel are gathered,
And a condensing cover including a lens unit disposed on an upper portion of the condensing type solar cell unit and provided for each portion in which each condensing type solar cell unit is located so as to condense light into the condensing type solar cell unit,
Wherein the lens cover is formed in a circular shape and includes a transmissive region through which light is directly transmitted to the non-condensing solar cell at a remaining portion except for the lens portion,
And a spacing frame which adjusts a spacing distance of the condenser cover in the cell support panel so that the focal point of the lens unit matches the condensing type solar cell unit,
The cover frame is formed so as to surround the side surface of the condensing cover. The panel frame is formed to surround the side surface of the cell supporting panel and is fitted to the cover frame. The cover frame and the panel frame are overlapped with each other And a fastening member for adjusting and fixing the height of the cover frame and the panel frame to each other. The method according to claim 1,
The cell supporting panel is formed with through-hole concentrating photovoltaic cells in which the condensing type solar cell unit is seated, and a surface in the opposite direction of the condensing type solar cell unit, Wherein the solar cell module is mounted so as to be exposed to the rear surface of the solar cell module. 3. The method of claim 2,
The condensing type solar cell unit
And a thermocouple attached to the light-collecting solar cell unit exposed at the rear surface of the cell supporting panel and generating heat by the light-collecting solar cell unit. The method of claim 3,
The thermocouple
And a heat sink for cooling the surface of the light collecting solar cell unit in order to generate a temperature difference on an opposite surface thereof. delete delete The method according to claim 1,
And a cover for supporting the condenser cover to prevent the condenser cover from being deformed by solar heat, the condenser cover having a wide upper end and a narrower shape toward the lower end. Solar module.

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