JPH02167846A - Solar cell-sealed window glass and production thereof - Google Patents

Abstract

PURPOSE:To improve the transparency and heat generation efficiency of the subject window glass by sealing a solar cell through a highly transparent resin layer such as silicone resin formed between a light-receiving surface such as plate glass and a back protecting plate such as polycarbonate plate. CONSTITUTION:A liquid resin R such as silicone resin is injected from a resin tank 4 into intervals 15 and 15 formed between a solar cell 13 and glass plates G1 and G2 with the pressure of compressed air through a resin-feeding flexible hose 7 and an injection opening 17. After the resin R is filled in the intervals 15 and 15, compressed air is charged in a closed space S formed between a laminate 12 and a supporting plate 10 through a hose 21 to press out the excess resin R in the laminate 12. Air bubbles generated in the laminate 12 and the excess resin are sucked with a vacuum pump 8 to give a limit injection amount of the resin R detected with the weight display meter 2a of a weight measurer. Valves 19 and 20 are subsequently closed and UV light, etc., is irradiated to cure the resin R for production of a solar cell-sealed window glass.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a solar cell-filled window glass used as a roof glass of an automobile, a rear window glass, a window glass of a building, or the like.

(Prior Art) It is known that recent passenger cars have a sliding roof that can be opened and closed on the ceiling of the car body, and use a windshield glass containing a solar cell as the sliding roof.

To manufacture such a window glass, as shown in FIG. 6, a thermoplastic resin film 100 such as polyvinyl butyral or ethylene vinyl acetate is layered on the plate glass G serving as the light-receiving surface, and a film 100 of thermoplastic resin such as polyvinyl butyral or ethylene vinyl acetate is layered on top of this resin film ioo. 10 solar cells
1 is placed on the solar cell 101, a resin film 100 similar to that described above is placed on top of the solar cell 101, a resin back sheet 102 is placed on top of this resin film 100, and this laminate is placed in an airtight bag 103 made of rubber or the like. The air inside the bag 103 is removed and the plate glass G, the resin 11i100, the solar cell 101, and the back sheet 102 are pressed together, and the bag is heated in an oven to melt the resin film 100 and join together.

(Problems to be Solved by the Invention) In the conventional method described above, in order to press the solar cell 101 against the glass plate G using vacuum suction force, the glass plate is bent and formed in advance.
If the bend is large, there is a disadvantage that the solar cell may break.

Furthermore, if the glass plate is bent and formed, air bubbles will remain between the solar cell 101 and the glass plate G even if the solar cell 101 is pressed with a certain amount of suction pressure.

Furthermore, polyvinyl butyral, ethylene vinyl acetate, and the like do not have high transparency, so there is a problem in terms of heat generation effect.

Furthermore, the backsheet 102 stacked to protect the solar cells 101 may fold, overlap, wrinkle, or be scratched during vacuum suction. If a hard material is used, the above-mentioned residual air bubbles will become more noticeable.

(Means for Solving the Problems) In order to solve the above problems, the present invention sets a solar cell with a gap between a plate glass forming a light-receiving surface and a protective plate such as a plate glass or a polycarbonate plate forming a back surface, A highly transparent resin such as silicone or epoxy resin is injected into this gap in liquid form and allowed to harden.

(Function) When enclosing a solar cell between glass plates or between a glass plate and another plate, the stress is not concentrated in one part of the solar cell, preventing damage, and silicone, etc. is added between the glass and the solar cell. A highly transparent product can be obtained by injecting it into

(Example) Embodiments of the present invention will be described below based on the accompanying drawings.

FIG. 1 is an overall view of a solar cell-filled window glass manufacturing apparatus according to the present invention, and FIG. 2 is a longitudinal cross-sectional view of a resin injection jig.
3 is an enlarged view of the main part of FIG. 2, FIG. 4 is a view taken in the direction of arrow A in FIG. 2, and FIG. 5 is a longitudinal cross-sectional view of the solar cell-filled window glass.

The manufacturing equipment can be carried in with the resin injection jig 2 placed on a trolley 3 on the weighing platform 1, and a resin tank 4 and a surplus liquid tank 5 are installed in a place separated from the weighing platform 1. is a resin R such as liquid silicone or liquid epoxy resin
Furthermore, the resin tank 4 is connected to a pressure air source 6 via a valve.
A flexible hose 7 for resin supply is led out from the bottom of the resin tank 4 via the pulp, and the residual liquid tank 5 is connected to a vacuum pump 8 and a flexible hose 9 for resin discharge is led out.

As shown in FIGS. 2 to 4, the resin injection jig 2 is provided with a gasket 11 on the front surface of an inclined support 10, so that the gasket 11 seals the peripheral edge of a laminate 12 that will become a window glass. I have to. Here, as shown in FIG. 3, in the laminate 12, the solar cell 13 with the wiring completed is placed between the plate glass G1 forming the light-receiving surface and the plate glass G2 forming the back surface via spacers 14... It is configured by setting a gap 15 and further interposing a sealing material 16 inside the periphery of the glass plates Gl and G2 except for the resin injection port. In addition, the plate glasses Gl and G2 are bent and formed in advance, and the plate glass G as a protective plate is used.
As an alternative to 2, a highly transparent and scratch-resistant plate such as a polycarbonate plate whose surface (the surface opposite to the solar cell) is hard-coated may be used.

The solar cell 13 is, for example, a transparent amorphous solar cell in which a three-layer amorphous silicone layer of P type, i type, and n type is formed on the surface of a glass substrate with a thickness of about 1 mm by a plasma deposition method using silane gas (SiH4) as a raw material gas. A battery is used, and the battery element constituting the solar cell 13 is not limited to a strip-shaped one that is long in the width direction as shown in the figure, but can be of any type.

Furthermore, the packing 11 and the spacer 14 are made of silicone or the like, and the packing 11 consists of a front packing 11a and a back packing llb, and when the front packing lla is removed from the back packing llb, the peripheral edge of the laminate 12 is placed between them. A confidential seal is created by pinching and tightening. Further, an inlet 17 is provided at the bottom of the packing 11, from which the tip of the flexible supply hose 7 faces, and a discharge port 18, from which the tip of the flexible discharge hose 9 faces, is provided at the top of the packing 11.
．． There is a manual valve 19 near the inlet and outlet of 9.
．． There are 20.

Further, a flexible hose 21 connected to the pressure air source 6 is connected to the back surface of the support plate 10 via a valve.

The procedure for manufacturing a window glass encapsulating a solar cell using the manufacturing apparatus configured as described above will be described below.

First, the intake valve 5a of the residual liquid tank 5 is opened, and the exhaust valve 4a of the resin tank 4 is closed, and compressed air is sent into the resin tank 4. Then, the liquid resin R such as silicone in the resin tank 4 is used for supply. Gap 15 between solar cell 13 and plate glasses Gl and G2 via flexible hose 7 and injection port 17
Get into it.

Once the gap 15 is filled with the liquid resin R, compressed air is sent into the airtight space S formed between the laminate 12 and the support plate 10 via the flexible hose 21 to remove excess liquid in the laminate 12. Push out resin R.

If air bubbles remain in the laminate 12, the air supply valve 5a of the residual liquid tank 5 is closed, the vacuum pump 8 is driven, and the air bubbles are removed while pressurizing from the back. Suction with a vacuum pump is carried out until the weight reaches the same amount as the injection amount (limit injection amount) that will not damage the solar cells. Further, the injection amount is detected by a weight indicator 18 attached to the weighing platform 1.

When the liquid resin R is filled into the gap 5 in this way, the manual valve 19.20 is closed, and the liquid resin is cured by irradiating it with ultraviolet rays or putting it in an oven, as shown in FIG. A window glass having a solar cell 3 sealed therein can be obtained.

(Effects of the Invention) As explained above, according to the present invention, a solar cell is set between two glass plates or resin plates with a gap, and liquid resin is injected into this gap to encapsulate the solar cell. This prevents the solar cells from being broken due to excessive force during the manufacturing process, and by using a plate glass or highly transparent polycarbonate plate for the back protection plate (and by using silicone or epoxy resin as the liquid resin), 1' for transparency
A solar cell-encapsulated window glass with high heat generation efficiency can be obtained. Furthermore, by using an amorphous silicon type solar cell, the solar cell itself can be made transparent to some extent, and can be used as a rear window, etc.

[Brief explanation of the drawing]

Fig. 1 is an overall view of a solar cell-filled window glass manufacturing apparatus according to the present invention, Fig. 2 is a vertical cross-sectional view of a resin injection jig, Fig. 3 is an enlarged view of the main parts of Fig. 2, and Fig. 4 is a FIG. 2 is a view taken in the direction of the arrow, FIG. 5 is a solar cell-filled window glass, and FIG. 6 is a diagram showing a conventional manufacturing method. In addition, in the drawing, 1 is a measuring platform, 2 is a resin injection jig, 4 is a resin tank, 5 is a residual liquid tank, 7, 9.21 is a flexible hose, 10 is a support plate, 11 is a packing, 13 is a solar cell, 15 is a gap, 17 is an inlet, 18 is an outlet, Gl, G
2 is plate glass. Patent applicant Nippon Sheet Glass Co., Ltd. Agent Patent attorney 2 1) Yong-Immediate inquiry
Patent Attorney Kuni Ohashi Patent Attorney
Yu Koyama Figure 3

Claims (5)

[Claims] (1) The light-receiving surface is a plate glass, the back side is a plate glass or a protective plate such as a polycarbonate plate, and a solar cell is sealed between the plate glass and the protective plate with a highly transparent resin layer such as silicone or epoxy resin interposed. Solar cell-filled window glass. (2) The solar cell-encapsulated window glass according to claim 1, wherein the solar cell is an amorphous silicon solar cell. (3) The solar cell-filled window glass according to claim 1, wherein the glass plate and the protection plate are bent in advance. (4) Set the solar cell between the glass plate that forms the light-receiving surface and the protective plate that forms the back surface so that there is a gap between the glass plate and the protective plate, and then seal the peripheral edges of the glass plate and the protective plate with packing. After sealing, liquid resin is injected into the gap from an injection port provided in a part of the packing, and the remaining liquid resin is discharged from a discharge port provided in a part of the packing. A method for manufacturing a solar cell-encapsulated window glass, characterized in that the resin is hardened. (5) The solar cell according to claim (4), wherein the liquid resin is injected with an injection port provided in a part of the packing being located downward and a discharge port being located upward. Method for manufacturing encapsulated window glass.