KR20200043712A - a Solar cell module - Google Patents

Abstract

The present invention provides a photovoltaic module with the improved generating efficiency. The photovoltaic module comprises: a non-concentrating photovoltaic cell with a square shape having torn edges; a cell support panel in which the non-concentrating photovoltaic cell is disposed; a plurality of concentrating type photovoltaic cell units respectively installed in uninstalled areas, which are formed since the torn edges of the non-collecting photovoltaic cells disposed in the cell support panel are gathered, and generated by sunlight; and a concentrating cover having a cover frame formed to surround sides of the cell support panel and a panel frame formed on top of the cover frame. In the concentrating cover, the plurality of non-collecting photovoltaic cells are attached to inside the cover frame.

Description

Solar cell module {a Solar cell module}

The present invention relates to a solar cell module that is formed by a combination of a condensing solar cell unit and a non-condensing solar cell, and is generated by sunlight.

In general, a solar cell is a device that is generated by solar light, and is formed in a flat plate shape, and is a non-condensing type solar cell that generates solar light across the board, and a condensing type that is generated by sunlight collected by a condensing device such as a lens. It is divided into solar cells.

On the other hand, a plurality of non-condensing type solar cells are arranged and installed on a flat plate, but the condensing type solar cells have a problem in that they are difficult to install together because a condensing device capable of condensing light must be located in front of the power plant.

In order to solve this, a hybrid solar cell of Korean Patent Registration No. 10-1217540 (2013.1.2.

A conventional hybrid solar cell is a hybrid solar cell comprising a condensing solar cell and a non-condensing solar cell in one type, comprising: a plurality of non-condensing solar cells that perform solar power generation by directly irradiating sunlight; One or more condensing solar cells that collect sunlight and perform solar power generation; A light collecting unit collecting and supplying sunlight to the one or more light collecting solar cells; And a light collecting unit that collects and supplies sunlight to the light collecting solar cell through the light collecting unit. And a solar tracking system that allows the sunlight incident through the condensing unit to be accurately condensed on the condensing solar cell, wherein the one or more condensing solar cells are buried in the non-condensing solar cell, and are fixed and biaxial. And a three-axis tracking system.

Such a conventional hybrid solar cell is installed in a form of embedding a condensing solar cell in a non-condensing solar cell to improve power generation efficiency of generating electricity by both condensing and non-condensing solar cells.

However, in the conventional hybrid solar cell, since the non-concentrated solar cell must be cut in order to embed the condensed solar cell in the non-condensed solar cell, damage to the non-condensed solar cell not only occurs, but also the cutting of the non-condensed solar cell There was a problem in that the power generation efficiency of the non-condensing solar cell was reduced.

In order to solve the above problems, the present invention can not only prevent the power generation efficiency from falling by installing a condensing solar cell without damaging the non-condensing solar cell, but also condensing the solar cell and the non-condensing solar. It is to provide a solar cell module that improves the power generation efficiency by efficiently arranging the cells and performing power generation simultaneously.

In order to achieve the above object, the present invention A non-condensing solar cell of square shape with incised edges; A cell support panel on which the non-condensing type solar cell is disposed; A plurality of condensing type solar cell units, which are respectively installed in uninstalled areas where cut edges of the non-condensing type solar cell arranged in the cell support panel are formed, and are generated by sunlight; And a light collecting cover having a cover frame formed to surround a side surface of the cell support panel, and a panel frame formed on the cover frame, wherein the light collecting cover includes a plurality of non-condensing suns inside the cover frame. Battery cells are attached.

In the cell support panel, a perforated light collecting cell seating hole in which the light collecting solar cell unit is seated is formed, and an opposite surface of the light collecting solar cell unit condensing and generating power is formed in the light collecting cell seating hole to support the cell. It can be seated to expose to the back of the panel.

The condensing type solar cell unit is attached to the back side of the condensing type power station that is generated by the sunlight, the circuit board on which the condensing type power station is mounted, and the condensing type power station is installed on the circuit board, and the condensing type power generation is performed. The heat sink radiating heat generated from the device and the condenser-type power plant are installed on the circuit board to reflect the condensed solar light through the condensing lens to provide the solar light to the condenser-type power plant. It may include a hollow condensing pipe having a reflective surface to reflect therein.

The light collecting cover, the support frame for supporting each of the cover frame and the panel frame, coupled to the support pipe, is provided spaced apart from the cell support panel, spaced apart by a spaced apart installation plate, and The cover frame and the panel frame may include coupling holes formed in upper and lower elongated holes, respectively, at portions where the panel frames are interconnected.

The support pipe may further include, on one side, a vent that is ventilated between the inside and the outside of the support pipe, and a waterproof cap that prevents rainwater from entering the upper portion.

The panel frame may further include a lens unit which is located at an upper portion and an upward direction of the condensing solar cell unit, and is installed at each portion where each condensing solar cell unit is positioned so as to collect light with the condensing solar cell unit. .

The solar cell module according to the present invention, by installing a condensing type solar cell unit in each empty space of a non-condensing type solar cell installed in a cell support panel, without damaging the non-condensing type solar cell, installs both, thereby generating power efficiency. Improve it.

In addition, the lens unit for condensing sunlight on the transmission cover and the transmission region for transmitting sunlight are divided, so that the condensing type solar cell unit and the non-condensing type solar cell can perform power generation simultaneously, and the sunlight passing through the lens unit In the middle, the diffusely reflected solar light is received from a non-concentrated solar cell to perform power generation, thereby improving power generation efficiency.

In addition, since a part of the light collecting solar cell can efficiently discharge heat from the light collecting cover, the efficiency of the light collecting solar cell may be increased.

In addition, the coupling hole may be coupled to the sun tracking device.

1 is a view showing a solar cell module according to an embodiment of the present invention,
Figure 2 is a view showing the separation plate of the solar cell module shown in Figure 1,
3 is a view showing a state in which the non-condensing heat solar cell is attached to the inside of the light collecting cover in the solar cell module shown in Figure 1,
4 is a view showing a state in which the solar cell module shown in Figure 1 is combined,
5 is a view showing a condensing type solar cell unit in the solar cell module shown in Figure 1,
FIG. 6 is a view showing a condensing pipe and a condensing power plant of the solar cell unit shown in FIG. 5.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar elements throughout the specification.

In addition, terms or words used in the present specification and claims should not be construed as being limited to ordinary or dictionary meanings, and the inventor appropriately defines the concept of terms in order to describe his or her invention in the best way. Based on the principle that it can be done, it should be interpreted as a meaning and a concept consistent with the technical idea of the present invention.

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

1 is a view showing a solar cell module according to an embodiment of the present invention, Figure 2 is a view showing the separation plate of the solar cell module shown in Figure 1, Figure 3 is the solar cell module shown in Figure 1 FIG. 4 is a view showing a state in which a non-condensing heat solar cell is attached to the inside of the light collecting cover, and FIG. 4 is a view showing a state in which the solar cell module shown in FIG. 1 is coupled, and FIG. 5 is a view showing the solar cell module shown in FIG. 1. It is a view showing a condensing type solar cell unit, and FIG. 6 is a view showing a condensing pipe and a condensing type power plant of the solar cell unit shown in FIG. 5.

1 to 6, the solar cell module according to the present invention includes a non-condensing type solar cell 100, a cell support panel 200, a condensing type solar cell unit 300, and a condensing cover 400 ).

The non-condensing type solar cell 100 may convert light energy of the sun into electrical energy.

On the other hand, the non-condensing type solar cell 100 can perform power generation in the form of converting light energy into electrical energy by the potential difference between the P-type semiconductor and the N-type semiconductor, and is a semiconductor made of an organic compound or silicon. It may be implemented.

In addition, the non-condensing type solar cell 100 may be configured in a flat plate shape to receive power from the sun and perform power generation, and may have a shape in which four corners are cut diagonally or curvedly in a square shape.

Here, the non-condensing type solar cell 100 is manufactured in the form of a circular semiconductor wafer. When the non-condensing type solar cell 100 is circular, it takes up a lot of installation space, so it reduces the installation space. It can be prepared by cutting into shape.

At this time, the non-condensing type solar cell 100 is made of 156mm Cell, and can be manufactured to increase practicality such as a lens or light convergence.

On the other hand, when the semiconductor wafer is cut into a square shape, since there are many cuts, the area of the semiconductor wafer is used as much as possible, and in order to minimize the installation space, the four edges are quadrilateral in a state where the edges of some semiconductor wafers are maintained around the periphery of the semiconductor wafer. It can be manufactured in the form of cutting.

Since the non-condensing solar cell 100 manufactured by transferring the circular semiconductor wafer as described above is manufactured in a square shape in which the squares are cut out, the installation space is minimized and the circular semiconductor wafer is cut and discarded. Can be minimized.

The cell support panel 200 is formed in the form of a square plate, and a plurality of non-condensing solar cells 100 may be arranged and installed in a lattice form.

On the other hand, the non-concentrated solar cell 100 installed in the cell support panel 200 is attached to the top surface of the non-concentrated solar cell 100, or the cell support panel 200 The condensing cell seating hole 210 into which the condensing type solar cell 100 is inserted may be formed to be installed in the form of being inserted into the condensing cell seating hole 210, and the non-condensing sun installed in the cell support panel 200 The battery cells 100 may be electrically connected to each other to collect and generate electricity.

In addition, the condensing solar cell unit 300 to be described below may be installed on the cell support panel 200. When the condensing solar cell unit 300 is described in detail below, the condensing solar cell unit 300 will be described together.

 The condensing type solar cell unit 300 may convert light energy into electrical energy by a potential difference, and converge sunlight to convert the collected light energy into electrical energy.

In addition, the condensing solar cell unit 300 is disposed on the cell support panel 200 and may be installed in each uninstalled area, which is an empty space where the corner portions are collected, that is, the non-condensing solar cell 100 is not installed.

And the condensing solar cell unit 300 is a plurality of condensing solar cell unit 300 is electrically connected to each other, or is electrically connected with the non-condensing solar cell 100 to collect and transfer the generated electricity to one place. You can.

To this end, the condensing type solar cell unit 300 may further include a condensing type power plant 310, a circuit board 320, a heat sink 330, and a condensing pipe 340. Here, the condensing power plant 310 can convert sunlight into electrical energy by a potential difference, and convert the condensed sunlight into electrical energy.

On the other hand, the condensing power plant 310 can be implemented with a semiconductor (Concentrator photovotaic, CPV) combined by the bonding of known heterogeneous compounds, and the condensing power plant 310 is a known configuration, so detailed description is omitted do.

In addition, the circuit board 320 may be mounted with a condenser-type power generator 310, and an electric element such as a diode, for example, for controlling electricity generated by the condensing-type power generator 310 may be mounted together. A circuit for electrically connecting the electrical elements and the condensing type power plant 310 may be formed on the circuit board 320.

Meanwhile, the circuit board 320 may be implemented as a metal PCB to facilitate heat dissipation.

In addition, the heat sink 330 may be attached to the surface of the circuit board 320 in the opposite direction in which the condensing power generator 310 is mounted on the circuit board 320, and the heat sink 330 is in contact with air. It is possible to have a plurality of heat sinks or heat sink fins or various types of heat sink structures to facilitate heat exchange due to the large area.

At this time, a portion of the circuit board 320 on which the condensing type power plant 310 is mounted is formed with a sink hole through which the condensing type power plant 310 and the heat sink 330 are directly contacted and can be aired. The energy-saving metal is seated on the ball, and heat generated from the light-converging power generator 310 may be transferred to the heat sink 330 through the heat-conducting metal to be dissipated.

On the other hand, the heat sink 330 may be formed of a metal material such as copper or aluminum with high heat dissipation or graphite.

In addition, the condensing pipe 340 may guide the sunlight by condensing the sunlight condensed from the condensing lens so that it is condensed by the condensing power plant 310.

On the other hand, the condensing pipe 340 may be formed in an empty pipe shape, and is vertically erected on a portion where the condensing power generator 310 is located on the circuit board 320, and reflects sunlight therein. It has a slope and can be condensed to a condensing power plant 310 through the reflection of sunlight incident on the end of the condensing pipe 340.

On the other hand, the condensing pipe 340 may be formed in a square pipe shape having the same area at the top and bottom, and the reflective surface, which is the inner surface of the condensing pipe 340, is perpendicular to the condensing power plant 310 and is incident. Through the reflection of the sunlight it can be guided to the concentrating power plant 310.

At this time, since the reflection surface of the condensing pipe 340 is vertically erected by the condensing type power plant 310, the incident angle of the sunlight entering the condensing pipe 340 is relatively wide since the focus of the condensing lens sunlight is collected. Solar power provided to the low-concentration power plant 310 is vertically provided, thereby improving power generation efficiency.

Here, due to the characteristics of the condensing type power plant 310, the generation efficiency increases as sunlight enters closer to the vertical of the condensing type power plant 310, and the meaning of “vertical” means the vertical line of the condensing type power plant 310. Means an angle of less than 45 °.

In addition, since the reflective surface of the condensing pipe 340 is perpendicular to the condensing type power plant 310, sunlight incident on the condensing pipe 340 does not flow out due to reflection, and all incident sunlight is condensed. Guided to the type power planter 310 can improve the power generation efficiency of the condensing type power planter 310.

Here, when the condensing pipe 340 is formed in a parabolic shape having a wide upper end and a narrow lower end, or an inverted trapezoid shape, the angle of reflection is relatively small and incident at an angle exceeding 45 ° with respect to the vertical line of the condensing power generator 310 Or, some of the sunlight is leaked to the outside through reflection, and thus, there is a problem in that the power generation efficiency of the concentrating power plant 310 is reduced.

On the other hand, the condensing pipe 340 is manufactured by bending a rectangular pipe in such a way that the reflective surface of a metal plate having a reflective surface, for example, an aluminum plate reflected on one surface of the aluminum, is located inside, or the reflective surface of the mirror is located inside. It is also possible to manufacture a plurality of mirrors by connecting them in a pipe form.

The light collecting cover 400 may be located on the top of the cell support panel 200 to collect light generated from the sun and provide it to the light collecting solar cell unit 300.

In addition, a plurality of non-condensing solar cells 100 may be attached to the light collecting cover 400 inside the cover frame. Due to this, it has the effect of spreading the light evenly by making scattered light.

In addition, the light collecting cover 400 may include a lens unit 410 or may include a lens unit 410 and a transmission area.

 In addition, the lens unit 410 may collect sunlight and provide it to the condensing type solar cell unit 300, and may be located in each portion where the condensing type solar cell unit 300 is installed in the condensing cover 400.

Meanwhile, the lens unit 410 may be formed in a circle having a radius as large as possible so that the lens unit 410 provided at a position corresponding to each condensing solar cell unit 300 does not overlap each other, and each lens unit ( 410 may be configured to focus on the condensing solar cell unit 300 corresponding to each lens unit 410.

In addition, the lens unit 410 is implemented in a form of forming concavo-convex patterns formed in different sizes on a plurality of concentric circles such as a Pronel lens so that sunlight is concentrated in the center, or a convex lens on the top of the light collecting cover 400 It can be installed in the light collecting cover 400 in the form of.

Here, the light collecting cover 400 forms a transparent area in the shape of a pattern around the periphery of the lens unit 410 on the pronel lens on which one lens unit 410 is formed, and the cell support panel 200 for a plurality of flannel lenses. It may be configured in a form of bonding to the size of, or may be configured to be installed by being supported by a frame so as to form a bonded form of each light collecting cover 400.

Further, even if the focus of the lens unit 410 is not exactly matched to the condensing type solar cell unit 300, when only the focus lens is incident, the light irradiated from the lens unit 410 by the focus lens to the solar cell unit 300 is correct. You can enter.

In addition, the light collecting cover 400 includes a cover frame 420, a panel frame 430, a supporting pipe 440, a spacer mounting plate 450, and a coupling hole 460 to satisfy the light collecting cover 400 ) May be further included.

Here, the cover frame 420 is formed to surround the side circumference of the light collecting cover 400, and the panel frame 430 is formed to surround the side circumference of the cell support panel 200 and may be disposed to be interconnected. Here, the cover frame 420 and the panel frame 430 may be integrally manufactured.

In addition, the support pipe 440 may support the cover frame 420 and the panel frame 430, respectively. In addition, the support pipe 440, the inside and outside of the support pipe 440 on one side, a vent (441) to ventilate heat generated by solar heat, and a waterproof cap to prevent rainwater from entering the vent (441) at the top. (442) may be further included.

And the spacer installation plate 450 is installed to be spaced below the support pipe 440, a ventilation unit may be installed. The ventilation unit, in addition to the condensing type solar cell unit 300, the heat sink 330 may be formed to prevent parts from being burned or burning due to heat accumulation. The separation space of the support frame may be formed by extending the length of the heat sink 330 or longer than the length.

In addition, the coupling holes 460 may be formed in upper and lower elongated holes, respectively, at portions where the cover frame 420 and the panel frame 430 overlap each other. That is, the coupling hole 460 may be combined with another light collecting cover 400 as well as a tracking device (not shown) that tracks the sun.

As described above, according to the solar cell module according to the present invention, non-condensing is performed by installing a condensing type solar cell unit 300 in every empty space of the non-condensing type solar cell 100 installed in the cell support panel 200. By installing both without damaging the type solar cell 100, power generation efficiency can be improved.

In addition, the lens unit 410 for condensing sunlight on the transmission cover and the transmissive area for transmitting sunlight are divided, so that the condensing solar cell unit 300 and the non-condensing solar cell 100 perform electricity generation at the same time. It is possible to improve power generation efficiency by receiving power from the non-condensing solar cell 100, which is diffusely reflected among the sunlight transmitted through the lens unit 410.

In addition, since a part of the condensing solar cell can efficiently discharge heat from the condensing cover 400, the efficiency of the condensing solar cell can be increased.

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 therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: non-condensing heat solar cell
200: cell support panel
210: light collector battery seating
300: condensing type solar cell unit
310: Concentrated power plant
320: circuit board
330: heat sink
340: condensing pipe
400: condensing cover
410: lens unit
420: cover frame
430: panel frame
440: support pipe
441: vent
442: Waterproof cap
450: Spaced installation plate
451: ventilation
460: joiner

Claims (6)

A non-condensing solar cell of square shape with incised edges;
A cell support panel on which the non-condensing type solar cell is disposed;
A plurality of condensing type solar cell units, which are respectively installed in uninstalled areas in which cut edges of the non-condensing type solar cell arranged on the cell support panel are formed, and are generated by sunlight; And
It includes a cover frame formed to surround the side of the cell support panel, and a light collecting cover having a panel frame formed on the cover frame,
The condensing cover,
A solar cell module, characterized in that a plurality of non-condensing type solar cell cells are attached inside the cover frame.
The method according to claim 1,
The cell support panel,
The condensing cell seating hole through which the condensing type solar cell unit is seated is formed, and in the condensing cell seating hole, a surface opposite to the power generated by condensing the solar cell unit is exposed to the rear surface of the cell support panel. Solar cell module characterized in that it is seated.
The method according to claim 2,
The condensing type solar cell unit,
A condensing type power station that is generated by the sunlight,
A circuit board on which the condensing type power plant is mounted,
A heat sink attached to a rear surface of the condenser type power plant installed on the circuit board to dissipate heat generated by the condenser type power plant element, and
A hollow type having a reflection surface therein that is installed in a portion where the condensing type power plant is mounted on the circuit board and reflects the condensed solar light through the condensing lens to provide the condensing type power source to the condensing type power plant. A solar cell module comprising a condensing pipe.
The method according to claim 3,
The condensing cover,
A support five supporting each of the cover frame and the panel frame,
It is combined with the support pipe, and is spaced apart from the cell support panel, is installed spaced apart, and spaced apart through the installation plate,
The cover frame and the panel frame is a solar cell module, characterized in that it comprises a coupling hole which is formed in the form of long holes in the upper and lower portions, respectively.
The method according to claim 4,
The support pipe,
On one side, a ventilation hole that is ventilated between the inside and the outside of the support pipe,
A solar cell module further comprising a waterproof cap to prevent rainwater from entering the upper portion.
The method according to claim 4,
The panel frame,
A solar cell module, characterized in that it further includes a lens unit located at an upper portion and an upward direction of the condensing solar cell unit to focus light on the condensing solar cell unit, and installed at each portion where each condensing solar cell unit is positioned. .

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