KR102515867B1 - Building integrated solar panel applying various pattern glass surface technology - Google Patents

Abstract

The present invention relates to a building-integrated solar panel to which glass surface technology of various patterns is applied, and more specifically, to enhance various aesthetics, tempered glass and solar cells, ethylene vinyl, etc., in which various pattern designs such as Rainy and Stone are expressed on the surface. It relates to a building-integrated solar panel to which a glass surface technology of various patterns having diversity, workability, safety and aesthetics is applied by laminating acetate (EVA) and polyethylene terephthalate (PET) structures.
The building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied includes pattern tempered glass 10 in which designs of various patterns are molded; A solar panel 20 laminated on one surface of the pattern tempered glass 10; and a black masking film 30 laminated on the other surface of the solar panel 20.

Description

Building integrated solar panel applying various pattern glass surface technology}

The present invention relates to a building-integrated solar panel to which glass surface technology of various patterns is applied, and more specifically, to enhance various aesthetics, tempered glass and solar cells, ethylene vinyl, etc., in which various pattern designs such as Rainy and Stone are expressed on the surface. It relates to a building-integrated solar panel to which a glass surface technology of various patterns having diversity, workability, safety and aesthetics is applied by laminating acetate (EVA) and polyethylene terephthalate (PET) structures.

In general, solar panels can be academically classified according to materials, shapes, and principles. Depending on the material, it is largely divided into silicon-based solar cell, compound-based solar cell, and organic-based solar cell. It is classified into a photoelectrochemical type such as a dye-sensitized type.

The efficiency of the solar panel is increased by being installed in an external facility where the sun directly hits, such as the outer wall or roof of a building. As a protective film to protect the solar panel as it is exposed to such an external environment for a long time, conventionally, a small linear expansion A glass substrate having various advantages such as coefficient, excellent gas barrier property, high light transmittance, high flatness, and excellent heat resistance and chemical resistance was used.

However, the glass substrate has disadvantages such as being weak against impact, being easily broken, being heavy due to its high density, and giving aversion to the design and construction of building-integrated photovoltaic power generation.

When the glass substrate used in the solar panel is replaced with a tempered glass substrate of various pattern designs, the solar panel itself can provide architectural elements and functionality, is strong against impact, and is made of ordinary glass when manufactured in a continuous process. Compared to substrates, it can have diversity, aesthetics, and economy.

On the other hand, in order to use a patterned tempered glass substrate for a solar panel, the substrate has oxygen and water vapor blocking properties to prevent aging of the solar panel, UV stability, and a small linear expansion coefficient to prevent distortion of the substrate due to process temperature change. and dimensional stability, high mechanical strength compatible with process equipment used for existing glass substrates, chemical resistance that can withstand etching processes, high light transmittance and low birefringence, surface scratch resistance, etc. are required, In particular, oxygen and water vapor blocking properties and UV stability are required.

In particular, the BIPV System has been developed in various ways, such as the form of opaque glass, the form of exterior materials combined with insulation, the form of finishing materials combined with roof, and the form of blinds.

One example of a technique for solving this problem is disclosed in Documents 1 to 2 below.

Patent Document 1 below includes vertical and horizontal frames arranged and fixed vertically and horizontally on the outer wall of a building, a plurality of fixing frames arranged and installed in a lattice form at regular intervals on the vertical and horizontal frames, and inserted into the fixing frames in one-to-one correspondence. And a plurality of solar cell panels composed of a plurality of solar cells to absorb the incident solar energy and convert it into electric energy, and connected to each solar cell panel to be drawn out along the inside of the vertical and horizontal frames. (+) and (-) wires, a terminal box connected to the (+) and (-) wires and connecting an external power supply object, and the (+) and (-) wires along the inside of the vertical and horizontal frames It is composed of a plurality of dummy wires connected to the wire and drawn out, and a line metering box connected to each of the dummy wires, and each dummy wire connected to the line metering box is assigned a unique number. A building-integrated photovoltaic power generation system is disclosed.

In Patent Document 2, the first and second supporting stages are provided on the left and right sides of the upper portion, and the first and second drainage portions are provided on the left and right sides of the lower portion, so that the upper portion of the fixing bar of the building is constant with each other. A plurality of main drainage guide pipes installed at intervals; A plurality of auxiliary drainage guide pipes arranged at regular intervals from each other, each of which has a drainage guideway and is installed orthogonally to the opposing main drainage guide pipe; A plurality of solar cell modules placed in the first and second holding stages of the main drainage guide pipe, the respective ends of which are mutually opposed to each other while sealing each space partitioned by the main drainage guide pipe and the auxiliary drainage guide pipe; About the building-integrated photovoltaic power generation roof comprising a; closing caps placed on the first and second supporting ends of each main drainage guide pipe to seal the space between them formed at the ends of the solar cell modules facing each other. has been initiated.

However, the conventional technology as described above is a technology related to a BIPV system, and the biggest disadvantage is that it is difficult to repair and has low aesthetics. For example, in the case of a roof-type solar panel, there are many problems such as an additional structure, heavy load, aesthetics, and workability.

Republic of Korea Patent Registration No. 10-1052763 (registered on July 25, 2011) Republic of Korea Patent Registration No. 10-1348089 (registered on December 30, 2013)

An object of the present invention has been made to solve the above-described problems, and protects the solar panel by laminating a plurality of various pattern design tempered glass and EVA, PET structures on the upper part of the solar panel, and at the same time, aesthetics and durability The purpose is to provide a building-integrated solar panel applied with glass surface technology of various patterns that can improve lightness, workability and safety.

In order to achieve the above object, the building-integrated solar panel 100 to which the glass surface technology of various patterns according to the present invention is applied is a solar panel having a pattern tempered glass 10 in which designs of various patterns are molded, and a plurality of solar cells. A black masking film 30 disposed between the light panel 20 and the pattern tempered glass and the solar panel to cover the white bus bar of the solar cell, and the pattern tempered glass 10 and the black masking film An ethylene vinyl acetate member 40 is inserted between the 30 and another ethylene vinyl acetate member 40 is inserted between the black masking film 30 and the solar panel 20, and the other On the lower surface of the solar panel 20 on which the ethylene vinyl acetate member 40 is laminated on the upper surface, a polyethylene terephthalate member 50 is laminated via another ethylene vinyl acetate member 40, and the pattern tempered glass ( 10) is characterized in that the pattern design 60 of any one of Rainy and Stone is expressed to enhance the aesthetics required by the building.

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In addition, the solar panel 20 is characterized in that it has a mono-crystal structure.

In addition, the building-integrated solar panel includes a charger 200 for charging the battery 300 with power provided by the solar panel; a battery 300 that is charged by receiving power from the charger 200; and a DC load 502 connected to the battery 300 to receive and consume the charged power.

In addition, the building-integrated solar panel includes a charger 200 for charging the battery 300 with power provided by the solar panel; a battery 300 that is charged by receiving power from the charger 200; an inverter 401 receiving direct current from the battery 300 and converting it into alternating current; and an AC load 501 connected to the inverter 401 to receive and consume the converted AC.

In addition, the building-integrated solar panel includes a charger 200 for charging the battery 300 with power provided by the solar panel; a battery 300 that is charged by receiving power from the charger 200; an AC/DC converter 402 that receives direct current from the battery 300 and converts it into alternating current; An AC load 501 connected to the AC/DC converter 402 to receive and consume the converted AC; a DC/DC converter 403 for receiving DC from the battery 300 and converting it into DC of a different voltage; and a DC load 502 connected to the DC/DC converter 403 to receive and consume the charged power.

As described above, the building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied has aesthetics because it can use various patterns compared to conventional solar panels, and a plurality of films and glass can be selected as needed. Since it can be laminated, it has excellent effects in productivity, economy, and workability.

In addition, by using the black masking cover technology, the white bus bar (white part) of the solar cell is not visible on the outside, thereby greatly improving aesthetics.

In addition, by designing patterns such as Rainy and Stone on the surface of tempered glass, various specifications and patterns representing various pattern designs can be expressed on the surface of the glass, and BIPV products with excellent aesthetics can be produced by realizing various front designs. There are possible effects.

In addition, as a BIPV function with excellent workability, it has the effect of realizing energy production at once as a building finishing material for roofs and exterior walls during on-site construction.

In addition, it has excellent durability and workability, so it can be applied to roofs and curtain walls such as building exteriors to form an exterior while producing solar power.

1 is a view showing types of pattern tempered glass used in a building-integrated solar panel to which glass surface technology of various patterns according to the present invention is applied.
Figures 2a to 2b is a view showing a building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied.
Figure 2c is a photograph of testing the strength of the building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied.
3a to 3d are views showing various structures of building-integrated solar panels to which glass surface technology of various patterns according to the present invention is applied.
4a to 4d are photographs showing examples in which the pattern tempered glass technology and the black masking film cover technology according to the present invention are applied.
5a to 5d are views showing examples of use of a building-integrated solar panel to which glass surface technology of various patterns according to the present invention is applied.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

The building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied includes patterned tempered glass 10 in which designs of various patterns are molded, and solar panel 20 laminated on one side of the patterned tempered glass 10. and a black masking film 30 laminated on the other surface of the solar panel 20 .

In addition, a polyethylene terephthalate member 50 may be attached to the other surface of the pattern tempered glass 10 .

As shown in FIG. 1, the pattern tempered glass 10 is a tempered glass in which various patterns such as Rainy and Stone are molded on its cross section, and has excellent pattern design and has excellent appearance and corrosion resistance, so that it can prevent rain or wind from the outside. It blocks, blocks noise and heat, and has a great function as an exterior finishing material.

That is, various pattern designs 60 are expressed on the surface of the pattern tempered glass 10 .

Therefore, by designing various patterns such as Rainy and Stone on the surface of the pattern tempered glass 10 represented by various pattern designs 60, it is possible to provide a solar cell that maximizes the aesthetics required by the building.

A desired pattern can be formed by spraying and applying a paint on one surface of the pattern tempered glass 10 .

That is, a pattern layer is formed by applying an inorganic paint to one side of the tempered glass by a silk printing technique.

Thereafter, the patterned tempered glass 10 may be manufactured by heating the tempered glass on which the pattern layer is formed for a predetermined time, quenching the heated tempered glass, and then cooling the tempered glass.

As shown in FIG. 2A, the solar panel 20 is divided into mono crystalline and poly crystalline, and in order to absorb the entire wavelength range of incident sunlight, the intermediate layer transmits a specific wavelength range It collects energy by reflecting or reflecting it and has flexibility.

The monocrystal is expensive, but has good efficiency and good durability. And in the case of polycrystal, the price is cheap but the efficiency is low.

As shown in FIG. 2B, the building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied includes a pattern tempered glass 10, a solar panel 20, an ethylene vinyl acetate member (EVA; 40), It is formed by laminating one or more of polyethylene terephthalate members (PET; 50).

As shown in FIG. 2C, the building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied includes a pattern tempered glass 10, a solar panel 20, an ethylene vinyl acetate member (EVA; 40), Close integration between the polyethylene terephthalate members (PET; 50) is possible, and structural stability and durability of the panel can be improved.

On the other hand, Figures 3a to 3f are views showing various structures of the building-integrated solar panel to which the glass surface technology of various patterns according to the present invention is applied.

As shown in FIG. 3A, the present invention attaches the solar panel 20 to the top of the pattern tempered glass 10 and attaches the black masking film 30 to the top of the solar panel 20, The solar panel 20 may be made of a structure in which the pattern tempered glass 10 and the black masking film 30 protect both sides.

To this end, the patterned tempered glass 10 used in the present invention has a unique pattern design among general-purpose tempered glass, and has excellent impact resistance, heat resistance, compatibility with other resins, and the like.

In addition, the present invention is integrated with the pattern tempered glass 10 and the black masking film 30 covering the solar panel 20 to reduce material by reducing empty space in the structure, and due to the nature of the structure, higher durability and strength than before can keep

On the other hand, in the conventional solar panel, the white bus bar (white part) of the solar cell does not look good in appearance, giving a serious aversion to requiring aesthetics in the finishing material of building materials, but the present invention provides a white bus through the black masking film 30 By covering the bar, it is possible to create a luxurious design.

Therefore, since the present invention can express various pattern designs with the pattern tempered glass 10 and the black masking film 30, it is aesthetically pleasing, and economical efficiency and workability are excellent by selecting and laminating a minimum number of films.

As shown in FIG. 3B, the present invention provides an ethylene vinyl acetate member 40 between the pattern tempered glass 10 and the solar panel 20 and between the solar panel 20 and the black masking film 30. may be made of a structure in which each is inserted.

The patterned tempered glass 10 is a material that endures in the temperature range of 500-600 ° C. with heat resistance, cold resistance, and weather resistance, and has a characteristic of self-extinguishing (flame retardancy) so that it does not spread even if a flame occurs and turns off, compared to general glass. Excellent durability.

The solar panel 20 is divided into mono crystalline and poly crystalline, and in order to absorb the entire wavelength range of the incident sunlight, the intermediate layer has a property of transmitting or reflecting a specific wavelength range.

The black masking film 30 contributes to covering the white bus bar of the solar cell due to its high durability, high melting point, and high adhesive strength.

The ethylene vinyl acetate member 40 is integrally attached to both sides of the solar panel 20, and prevents corrosion due to moisture penetration and protects the solar panel 20 from impact.

In addition, the ethylene vinyl acetate member 40 is an essential material for maintaining the life of the solar panel 20 for a long time, and is located on the front and rear surfaces of the solar cell to serve as a buffer to prevent damage to the solar cell.

Therefore, the ethylene vinyl acetate member 40 is inserted between one surface of the pattern tempered glass 10 and the solar panel 20 and between the solar panel 20 and the black masking film 30, respectively, to achieve self-extinguishing properties ( flame retardant), it does not spread even when flames occur, protects so that the characteristics of turning off are expressed, and can serve as a buffer material to prevent damage to solar cells.

Therefore, in the present invention, when the solar panel 20 made of a monocrystal receives an impact, it can be prevented as much as possible by the ethylene vinyl acetate members 40 on both sides.

In addition, the present invention is a convergence product with the solar panel 20 by maximizing the characteristics of the ethylene vinyl acetate member and the pattern tempered glass, and is suitable for aesthetics, versatility, durability, weather resistance, and workability, making it easy to construct and fire resistant. to provide safe solar panels.

As shown in FIG. 3C, the present invention is between the pattern tempered glass 10 and the black masking film 30, between the black masking film 30 and the solar panel 20, the solar panel 20 Ethylene vinyl acetate members 40 are inserted between the and polyethylene terephthalate members 50, respectively, and the pattern design 60 may be expressed on the surface of the pattern tempered glass 10.

The lower the concentration of gallium (Ga) doped in the zinc oxide of the solar panel 20 transmits light in a long wavelength band, and the higher the concentration of gallium (Ga) transmits light in a short wavelength band.

The ethylene vinyl acetate member 40 has very different characteristics depending on the content of VA (Vinyle Acetate), and the ethylene vinyl acetate for solar panels according to the present invention has a VA content of about 28 to 33%, -( It is composed of CH2-CH2)6.14-(CH2-CHAc)-.

As shown in FIG. 3D, in the present invention, an ethylene vinyl acetate member 40 is inserted between the pattern tempered glass 10 and the solar panel 20, and the surface of the solar panel 20 is black masked It may be made of a structure to which the film 30 is attached.

The ethylene vinyl acetate member 40 is an essential material for maintaining a long lifespan of the solar panel, and is located on the front and rear surfaces of the solar cell to serve as a buffer to prevent damage to the solar cell.

Therefore, in the present invention, by inserting the ethylene vinyl acetate member 40 between the pattern tempered glass 10 and the solar panel 20, the aesthetics of the pattern tempered glass 10 and the durability to prevent damage to the solar cell can be saved at the same time. there is.

Meanwhile, materials described below may be formed integrally with or independently of the solar panel 20 .

The above-described ethylene vinyl acetate member 40 may be replaced with a material selected from polyolefin, inomer, silicone resin, and polyvinyl butyral (PVB).

In addition, the solar panel 20 has a monocrystalline structure, TPT (Tedlar/PET/Tedlar), TPE (Tedlar/PET/EVA), TAT (Tedlar/Alfoil/Tedlar), One of TPAT (Tedlar/PET/Al foil/Tedalr), TPOT (Tedlar/PET/Oxide/Tedlar), PAP (PEN/Al foil/PET), or Polyester can be stacked.

In addition, instead of the pattern tempered glass 10, it may be formed of ethylene-chlorofluoroethylene having a moisture transmittance of 100 g / m 2 / day or more, and the additional sealing material is formed of a material having a moisture transmittance of 10 g / m 2 / day or less It could be.

For example, a newly applied inomer has a water vapor transmission rate (WVTR) of 1 g / m 2 / day or less, and a polyolefin has a water vapor transmission rate of 5 g / m 2 / day or less, Ethylene vinyl acetate (EVA) has a moisture transmission rate of approximately 20 g / m 2 / day to 40 g / m 2 / day, polyvinyl butyral (PVB) has a moisture transmission rate of 30 g / m 2 / day to 50 g / m 2 / day, The silicone resin has a moisture permeability of 150 g/m 2 /day or more.

As the rear sheet of the solar panel 20, TPT (Tedlar/PET/Tedlar), TPE (Tedlar/PET/EVA), TAT (Tedlar/Al foil/Tedlar), TPT (TPAT; Tedlar/PET/Al foil/Tedalr), TPOT (Tedlar/PET/Oxide/Tedlar), PAP (PEN/Al foil/PET), or Polyester. there is.

As another embodiment, the rear side of the mono-crystal structured solar panel 20 includes Tedlar/Polyester/EVA (“TPE”), in which the TED is protected against the environment. is the outermost layer, polyester provides additional electrical isolation, and EVA is a thin layer linked with an encapsulant.

Also, alternatives to TPEs for use as the back sheet of a mono-crystal structure or poly-crystal structure solar panel 20 may include, for example, Tedra/Polyester/Tedra ("TPT").

As another embodiment, the solar panel 20 having a mono-crystal structure is made of ethylene vinyl acetate (EVA), silicone resin, polyvinyl butyral (PVB), polyolefin, and inomer. It can be laminated with selected materials.

As another embodiment of the present invention, instead of the ethylene vinyl acetate member 40, it may be formed of a material having a moisture transmittance of 100 g / m 2 / day or more, and having a moisture transmittance of 20 g / m 2 / day to 50 g / m 2 / day It may be formed of a material, and the additional sealing material may be formed of a material having a water permeability of 10 g/m 2 /day or less.

For example, polyolefin, ethylene vinyl acetate (EVA), polyvinyl butyral (PVB), silicone resin, TPT (Tedlar/PET/Tedlar), TPE (Tedlar/ PET/EVA), TAT (Tedlar/Al foil/Tedlar), TPAT (Tedlar/PET/Al foil/Tedalr), TPOT (Tedlar/PET/Oxide/Tedlar), PAP (PAP; PEN/Al foil/PET) or PET (Polyester).

In addition, instead of the polyethylene terephthalate member 50, it may be formed of a material having a moisture transmittance of 100 g / m 2 / day or more, and may be formed of a material having a moisture transmittance of 20 g / m 2 / day to 50 g / m 2 / day, The additional sealing material may be formed of a material having a moisture permeability of 10 g/m 2 /day or less.

For example, polyolefin, ethylene vinyl acetate (EVA), polyvinyl butyral (PVB), silicone resin, TPT (Tedlar/PET/Tedlar), TPE (Tedlar/ PET/EVA), TAT (Tedlar/Al foil/Tedlar), TPAT (Tedlar/PET/Al foil/Tedalr), TPOT (Tedlar/PET/Oxide/Tedlar), PAP (PAP; PEN/Al foil/PET) or PET (Polyester).

In addition, the material laminated on the pattern tempered glass 10 and the solar panel 20 laminated on the pattern tempered glass 10 is at least polypropylene, polycarbonate, polymethyl methacrylate, polyacrylate, and polypropylene. It may contain vinyl chloride, polyacetate resin, casting resin, acrylate, fluorinated ethylene propylene, polyvinyl fluoride, and/or ethylene tetrafluoroethylene.

As shown in FIGS. 4A to 4D, the black masking film 30 used in the building-integrated solar panel 100 of the present invention covers the white bus bar of the solar cell to increase the aesthetics of the solar panel, thereby increasing acceptance by consumers. As a material for increasing, the general tape melts in the laminating process at high temperature, but the black masking film 30 is not affected.

In addition, by designing various patterns such as Rainy and Stone on the surface of the pattern tempered glass 10 expressed in various pattern designs, it is possible to provide a solar cell that maximizes the aesthetics required by the building.

Hereinafter, examples of use of the building-integrated solar panel to which the glass surface technology of various patterns configured as described above is applied will be described.

As shown in FIG. 5A, the charger 200 connected to the building-integrated solar panel 100 through the reverse current prevention diode 150 and the battery 300 connected again through the reverse current prevention diode 150 are connected. When the switch 310 is turned on, the LED 600 is operated.

As shown in FIG. 5B, the charger 200 connected to the building-integrated solar panel 100 through a reverse current prevention diode 150 and the battery 300 connected again through a reverse current prevention diode 150 and the An AC load 501 is connected to an inverter 401 that receives direct current (DC) from the battery 300 and converts it to alternating current (AC).

As shown in FIG. 5C, the charger 200 connected to the building-integrated solar panel 100 through a reverse current prevention diode 150 and the battery 300 connected again through a reverse current prevention diode 150 and the The AC load 501 is connected through the inverter 401 that receives DC from the battery 300 and converts it to AC, and the LED operates when the switch 310 connected to the battery 300 is turned on. 600 is connected.

As shown in FIG. 5D, the AC/DC converter 402 for receiving the direct current of the battery 300 charged by the building-integrated solar panel 100 and the charger 200 and converting it into alternating current, and direct current as necessary An AC load 501 and a DC load 502 are respectively connected to a DC/DC converter 403 that converts into voltage or into DC for stabilization.

On the other hand, regarding the bonding method of the pattern tempered glass 10, solar panel 20, black masking film 30, ethylene vinyl acetate member 40, polyethylene terephthalate member 50, pattern design 60, etc. Although described as follows, it is not limited thereto.

In the present invention, the pattern tempered glass 10, the solar panel 20, and the polyethylene terephthalate member 50 are attached by introducing any one of acrylic, ethylene vinyl acetate, and urethane-based adhesives having heat resistance and heat dissipation performance to form an adhesive layer.

In particular, the adhesive has excellent adhesion to a material constituting the heat conductive layer, such as tempered glass, so that solid adhesion is possible.

On the other hand, in order to improve the durability of the pattern tempered glass 10 and the like and prevent deformation against ultraviolet (UV), hard coating and ultraviolet (UV) blocking treatment may be further included. More specifically, hard coating is applied to prevent scratches, or anti-glare coating and anti-reflection coating films reduce glare by suppressing reflected light and diffuse reflection.

Although the present invention has been described with reference to the preferred embodiments with reference to the accompanying drawings, it is clear that various modifications are possible to those skilled in the art from this description without departing from the scope of the present invention. Accordingly, the scope of the present invention should be construed by the claims described to include examples of these many variations.

10: pattern tempered glass
20: solar panel
30: black masking film
40: Absence of ethylene vinyl acetate
50: Polyethylene terephthalate member
60: pattern design
100: building-integrated solar panel
150: reverse current prevention diode
200: charger
300: battery
310: switch
401: Inverter
402: AC/DC converter
403: DC/DC converter
501 AC load
502: DC load
600: LEDs

Claims (10)

The patterned tempered glass 10 in which designs of various patterns are molded, the solar panel 20 having a plurality of solar cells, and the patterned tempered glass and the solar panel are disposed to form a white bus bar of the solar cell. Including a black masking film 30 that covers,
An ethylene vinyl acetate member 40 is inserted between the pattern tempered glass 10 and the black masking film 30, and another ethylene vinyl acetate member 40 is inserted between the black masking film 30 and the solar panel 20. Acetate member 40 is inserted,
A polyethylene terephthalate member 50 is laminated on the lower surface of the solar panel 20 on which the other ethylene vinyl acetate member 40 is laminated on the upper surface, via another ethylene vinyl acetate member 40,
On the surface of the pattern tempered glass 10, any one of Rainy and Stone pattern designs 60 are expressed to enhance the aesthetics required by the building. panel.
delete delete delete delete delete The method of claim 1,
The solar panel 20 is a building-integrated solar panel to which glass surface technology of various patterns is applied, characterized in that it has a mono-crystal structure.
According to claim 1 or claim 7,
The building-integrated solar panel includes a charger 200 for charging the battery 300 with power provided by the solar panel;
a battery 300 that is charged by receiving power from the charger 200; and
A building-integrated solar panel to which glass surface technology of various patterns is applied, characterized in that a DC load 502 connected to the battery 300 to receive and consume the charged power.
According to claim 1 or claim 7,
The building-integrated solar panel includes a charger 200 for charging the battery 300 with power provided by the solar panel;
a battery 300 that is charged by receiving power from the charger 200;
an inverter 401 receiving direct current from the battery 300 and converting it into alternating current; and
An AC load 501 connected to the inverter 401 to receive and consume the converted AC; building-integrated solar panel applying glass surface technology of various patterns, characterized in that connected.
According to claim 1 or claim 7,
The building-integrated solar panel includes a charger 200 for charging the battery 300 with power provided by the solar panel;
a battery 300 that is charged by receiving power from the charger 200;
an AC/DC converter 402 that receives direct current from the battery 300 and converts it into alternating current;
An AC load 501 connected to the AC/DC converter 402 to receive and consume the converted AC;
a DC/DC converter 403 for receiving DC from the battery 300 and converting it into DC of a different voltage; and
A building-integrated solar panel to which glass surface technology of various patterns is applied, characterized in that a DC load 502 connected to the DC/DC converter 403 to receive and consume the charged power.

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