KR102190655B1 - The photovoltaic module manufactured from solar cells using glass substrates - Google Patents

Abstract

According to the present invention, provided is a photovoltaic module manufactured with a solar cell using a glass substrate. The photovoltaic module includes: front protection glass; a photoelectric transformation module deposited on the rear side of the front protection glass, and generating electric energy with sunlight inputted through the photoelectric transformation module; a sealing material sealing the photoelectric transformation module and the front protection glass to protect the photoelectric transformation module and the front protection glass from moisture or external foreign substances and protect the photoelectric transformation module and the front protection glass from an external collision or external shock; front main glass installed on the front side of the front protection glass packed with the sealing material to protect the photoelectric transformation module and the front protection glass from an external shock or collision or an external environment; and rear main glass installed on the rear side of the photoelectric transformation module packed with the sealing material to protect the photoelectric transformation module from an external shock or collision or the external environment. Therefore, the present invention is capable of reducing costs for manufacturing a photovoltaic module by using a semiconductor film deposition process.

Description

Solar modules manufactured using solar cells using glass substrates {The photovoltaic module manufactured from solar cells using glass substrates}

The present invention relates to a solar module manufactured using a solar cell using a glass substrate.

Recently, the use of solar power generation facilities capable of generating electric power using solar energy has become increasingly common.

Solar cells using such solar energy do not use fossil fuels such as coal or petroleum, are pollution-free, and are in the spotlight as a new alternative energy source in the future by using sunlight, which is an infinite energy source. , It is used to obtain power generation for buildings, automobiles, etc.

In general, photovoltaic power generation is a technology that generates electricity using solar cells (PV: Photovoltaic).

The solar cell is a semiconductor device that converts light energy into electrical energy using a photoelectric effect, and a plurality of solar cells are connected in series or in parallel to generate a voltage and current required by a user.

However, the conventional solar module has a problem in that the manufacturing cost is high as a solar cell using a silicon wafer is used.

On the other hand, as a prior art of the present invention, there is a "solar cell module" filed and published under the application number "10-2014-0013203". The solar cell module includes a plurality of solar cells, and the front and rear sides of the solar cell A front substrate and a rear substrate respectively positioned, and a sealing member positioned between the front substrate and the rear substrate and sealing the solar cell, wherein the front substrate and the rear substrate are each formed of glass or ceramic, and the A colored layer is located on the inner surface of the rear substrate facing the solar cell.

Korean Patent Publication No. "10-2015-0092616" (2015.08.13)

Accordingly, an object of the present invention is to provide a solar module with a lower manufacturing cost by using a thin film solar cell in order to solve the above problems.

A solar module manufactured using a solar cell using a glass substrate according to the present invention for achieving the above object includes: a front protective glass; A photoelectric conversion module that is deposited on the rear surface of the front protective glass and generates electric energy using sunlight incident through the front protective glass; A sealing material that seals the front protection glass and the photoelectric conversion module to protect the front protection glass and the photoelectric conversion module from moisture or external foreign substances, and protects the photoelectric conversion module and the front protection glass from external impact or external collision; A front main glass installed on the front of the front protective glass wrapped with the sealing material to protect the front protective glass and the photoelectric conversion module from external impact, collision, or external environment; And a rear main glass installed on the rear surface of the photoelectric conversion module packaged with the sealing material to protect the photoelectric conversion module from external impact, collision, or external environment.

A solar module manufactured using a solar cell using a glass substrate according to the present invention having such a structure is a solar cell manufacturing process, which uses a process of depositing a semiconductor thin film on an inexpensive glass or metal substrate instead of a silicon wafer. Can lower the manufacturing cost of

Figure 1 is a longitudinal sectional view of the present invention,
Figure 2 is a longitudinal sectional view of the photoelectric conversion module equipped in the present invention,
Figure 3 is a diagram showing an insulating groove processed in the photoelectric conversion module,
Figure 4 is a plan view of the present invention,

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

As shown in Figure 1, a solar module manufactured using a solar cell using a glass substrate according to the present invention includes: a front protective glass 1 (Glass); A photoelectric conversion module (2) deposited on the rear surface of the front protective glass (1) and generating electric energy by using sunlight incident through the front protective glass (1); The front protection glass 1 and the photoelectric conversion module 2 are sealed to protect the front protection glass 1 and the photoelectric conversion module 2 from moisture or external foreign substances, and the photoelectric conversion module ( 2) and a sealing material 3 for protecting the front protective glass 1; The front main glass 4 is installed on the front of the front protective glass 1 wrapped with the sealing material 3 to protect the front protective glass 1 and the photoelectric conversion module 2 from external impacts, collisions, or external environments. Glass); And a rear main glass 5 (Glass) installed on the rear surface of the photoelectric conversion module 2 packaged with the sealing material 3 to protect the photoelectric conversion module 2 from external impact, collision, or external environment. .

As shown in Fig. 2, the photoelectric conversion module 2 includes a solar cell 21 for generating electric energy using incident sunlight; A transparent electrode layer 22 bonded to the p-Si thin film layer 211 provided on the solar cell 21 as a transparent conductive material installed on the entire surface of the solar cell 21; And a rear electrode layer 23 bonded to the n-Si thin film layer 213 provided on the solar cell 21 as a conductive material installed on the rear surface of the solar cell 21.

The transparent electrode layer 22 is deposited on the rear surface of the front protective glass 1, and the solar cell 21 is a p-Si thin film layer 211 deposited on the transparent electrode layer 22, as shown in FIG. ), an i-Si thin film layer 212 deposited on the p-Si thin film layer 211, an n-Si thin film layer 213 deposited on the i-Si thin film layer 212, and the n-Si thin film layer 213 It includes a rear reflective film 214 deposited on.

The rear electrode layer 23 is deposited on the rear reflective layer 214 and bonded to the n-Si thin film layer 213.

The rear reflective layer 214 is made of ZnO, and improves reflection from the rear surface of the n-Si thin film layer 213 to help re-absorption of light to the i-Si thin film layer 212.

In the transparent electrode layer 22, a SnO:F, ZnO:Ga, ZnO:Al, or ZnO:B thin film is deposited on the rear surface of the front protective glass 1 by sputtering or CVD.

The transparent electrode layer 22 should have low specific resistance for low series resistance and high charge collection, and high transmittance so as to minimize light loss.

Usually, the p-Si thin film layer 211 is deposited very thinly about 15 nm to 25 nm, and in the case of a single junction, the i-Si thin film layer 212 is manufactured about 300 nm to 400 nm.

The p-Si thin film layer 211 and the n-Si thin film layer 213 do not actually participate in light absorption and only provide electromotive force.

A constant electric field is applied inside the i-Si thin film layer 212 used as the light absorption layer, and electrons and holes generated in the i-Si thin film layer 212 follow the electric field, respectively, the n-Si thin film layer 213 and the p-Si thin film layer Collected at 211.

In the photoelectric conversion module 2 in which one end edge faces the one end edge of the front protective glass 1, as shown in FIG. 3, a photoelectric conversion module 2 is 10 mm to 40 mm away from the one end edge of the photoelectric conversion module 2. A linear insulating groove 24 for cutting the conversion module 2 in the thickness direction of the photoelectric conversion module 2 is processed.

The insulating groove 24 prevents current from leaking from the edge of one end of the photoelectric conversion module 2.

The sealing material 3 is made of EVA (Ethylene Vinyl Acetate) or PVB (Poly Vinyl Butyral).

In order to prevent leakage of the current generated from the photoelectric conversion module 2, the horizontal and vertical widths of the front protection glass 1 and the photoelectric conversion module 2 are as shown in FIG. 4, and the front main glass (4) Or it is made 20mm to 80mm smaller than the horizontal and vertical widths of the rear main glass 5.

Two or more of the photoelectric conversion modules 2 may be installed side by side, and as shown in FIG. 4, a gap of 1 mm to 5 mm is formed between the two photoelectric conversion modules 2 installed side by side, When the adjacent installed photoelectric conversion modules 2 are thermally expanded, they do not collide with each other.

The solar module manufactured using a solar cell using a glass substrate according to the present invention having such a structure is a solar cell 21 manufacturing process by using a process of depositing a semiconductor thin film on an inexpensive glass or metal substrate instead of a silicon wafer. The manufacturing cost of solar modules can be lowered.

1. Front protection glass 2. Photoelectric conversion module
21. Solar cell 211. p-Si thin film layer
212.i-Si thin film layer 213.n-Si thin film layer
214. Rear reflective layer 22. Transparent electrode layer
23. Back electrode layer 24. Insulation groove
3. Sealing material 4. Front main glass
5. Rear main glass

Claims (4)

A front protective glass 1 (Glass);
A photoelectric conversion module (2) deposited on the rear surface of the front protective glass (1) and generating electric energy by using sunlight incident through the front protective glass (1);
The front protection glass 1 and the photoelectric conversion module 2 are sealed to protect the front protection glass 1 and the photoelectric conversion module 2 from moisture or external foreign substances, and the photoelectric conversion module ( 2) and a sealing material 3 for protecting the front protective glass 1;
The front main glass 4 is installed on the front of the front protective glass 1 wrapped with the sealing material 3 to protect the front protective glass 1 and the photoelectric conversion module 2 from external impacts, collisions, or external environments. Glass);
And a rear main glass 5 (Glass) installed on the rear surface of the photoelectric conversion module 2 packaged with the sealing material 3 to protect the photoelectric conversion module 2 from external impact, collision, or external environment, and ,
In order to prevent leakage of the current generated from the photoelectric conversion module 2, the horizontal and vertical widths of the front protective glass 1 and the photoelectric conversion module 2 are the front main glass 4 or the rear main glass ( It is manufactured 20mm to 80mm smaller than the horizontal and vertical width of 5),
Two or more of the photoelectric conversion modules 2 are installed side by side,
A gap of 1 mm to 5 mm is formed between the two photoelectric conversion modules 2 installed side by side, so that the adjacent installed photoelectric conversion modules 2 do not collide with each other when thermally expanded,
In the photoelectric conversion module 2 whose one end edge faces one end edge of the front protective glass 1, a photoelectric conversion module 2 that is 10 mm to 40 mm away from one end edge of the photoelectric conversion module 2 is photoelectrically converted. A linear insulating groove 24 cut in the thickness direction of the module 2 is processed,
The photoelectric conversion module 2 includes a solar cell 21 that generates electric energy using incident sunlight,
A transparent electrode layer 22 bonded to the p-Si thin film layer 211 provided in the solar cell 21 as a transparent conductive material installed on the entire surface of the solar cell 21,
And a rear electrode layer 23 bonded to the n-Si thin film layer 213 provided in the solar cell 21 as a conductive material installed on the rear surface of the solar cell 21,
The transparent electrode layer 22 is deposited on the rear surface of the front protective glass 1,
The solar cell 21 includes a p-Si thin film layer 211 deposited on the transparent electrode layer 22,
I-Si thin film layer 212 deposited on the p-Si thin film layer 211,
An n-Si thin film layer 213 deposited on the i-Si thin film layer 212,
And a rear reflective film 214 deposited on the n-Si thin film layer 213,
The rear electrode layer 23 is deposited on the rear reflective layer 214 and bonded to the n-Si thin film layer 213,
The rear reflective layer 214 is made of ZnO, and helps re-absorption of light to the i-Si thin film layer 212 by enhancing reflection from the rear surface of the n-Si thin film layer 213,
The thickness of the p-Si thin film layer 211 is 15nm to 25nm,
A solar module manufactured using a solar cell using a glass substrate, wherein the i-Si thin film layer 212 has a thickness of 300 nm to 400 nm.
delete delete delete

Images