JPS6011507Y2 - solar cell substrate structure - Google Patents

Description

[Detailed explanation of the idea] The present invention relates to a solar cell substrate structure.

In general, solar cells generate a low voltage per chip, so by arranging multiple solar cells and electrically connecting them in series, the voltage required by the load section can be created. There is.

As shown in FIG. 1, the solar cell connection structure is such that solar cells 10 and 10' are arranged in an oblique manner in an orderly manner, and adjacent solar cells 10 and 10' are connected via a conductive member. However, this structure exposes the ends of the solar cells 10, which is unsightly, and also reduces the thickness t of the overlapped portion of the solar cells 10 and 10'. This is undesirable as it contradicts the ideal of a watch, which is constantly striving to be larger and thinner.

Furthermore, as shown in FIG. 2, there is a structure in which solar cells 10, 10' are arranged in a plane and an electrical connection is made between them by bonding a conductive member 40 such as a wire, but this bonding process is extremely difficult, and furthermore,
There is a risk that the wires may be accidentally cut when handling the solar cells that have been connected.

The present invention was developed in view of the above-mentioned problems, and is based on a structure of a solar cell in which one side of the solar cell is provided with at least one upper electrode part, and the other side of the solar cell is fixed to a printed wiring board. A part of the substrate is bent and connected to the upper electrode portion of the solar cell, and the electrical connection between the solar cells can be easily and reliably made, and the device is easy to handle. The purpose is to provide a convenient solar cell substrate structure.

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

FIG. 3 shows an embodiment of the present invention, in which 10 is a solar cell having one electrode section 11 on the top surface and the other electrode section 12 on the bottom surface, and 20a and 20b are printed wirings 21a and 21b on the top surface, respectively. This is an insulating flexible sheet substrate with

20c is a connecting board that connects 20a and 20b, and a portion thereof is provided with a substantially U-shaped cut 22.

When the broken line portion 23 is bent at the base of the cut 22, two upper and lower substrates 20a and 20b are formed as shown in FIGS. 4 and 5.
It looks like they are superimposed on each other.

The solar cell 10 has printed wiring 21a on the lower substrate 20a.
The lower electrode 12 of the solar cell 10 is fixed at a predetermined position on the printed wiring 21 by soldering.
It will be electrically connected to a.

On the other hand, the upper surface electrode 11 of the solar cell 10 is connected to the upper substrate 20b.
Similarly, it is fixed to a predetermined position on the printed wiring 21b by soldering, and is electrically connected to the printed wiring 21b.

In this way, the solar cell 10 is sandwiched between both substrates 20a and 20b, and electrical connections are made between the plurality of solar cells.

Reference numeral 30 denotes a metal substrate with legs 31 provided on its lower surface, and the legs 31 are inserted into the module and fixed with screws.

The lower substrate 20a has a metal substrate 30 to correct warping.
It is glued and fixed to the top surface of.

Approximately U formed when the connecting board 20c is bent
The convex portion 24 is used as a lead terminal portion for connecting the printed wiring 21a or 21b to the module.

A time display window 50a is provided on the lower substrate 20a, and a time display window 50a is provided on the upper substrate 20a.
A time display window 50b and a solar cell window 60 are respectively provided in 20b, and the positioning of both 20a and 20b is performed by display windows 50a and 50b having the same shape.
The light-receiving surface of the solar cell 10 is exposed through the solar cell window 60.

Note that positioning may be performed using the outer shapes of both 20a and 20b or a portion thereof.

70 is a diode, and 80 is a resistor.

With the above configuration, the two substrates 20a and 20b are integrally formed, and the printed wiring 21a.

Since 21b only needs to be applied on one side of the substrate, the production of the solar cell substrate is advantageous and the manufacturing cost can be reduced.

In addition, since the exposed portion of the upper surface of the lower substrate 20a can be hidden by the upper substrate 20b, the printed wiring 21a is not damaged by touching it directly, and the solar cell 10 is also placed between the two substrates 20a and 20b. The solar cell substrate is sandwiched between the substrates, making it less susceptible to external contact and protecting the inside of the solar cell substrate.

Further, the connecting board 20c not only connects the two boards 20a and 20b, but also serves as a lead terminal portion, and the present invention has high practical value as a structure that effectively utilizes the entire board.

[Brief explanation of the drawing]

Figures 1 and 2 are side views of the conventional embodiment, Figures 3 to 5 are the embodiments of the present invention, Figures 3 and 4 are top views, and Figure 5 is a side view. be. 10.10'...Solar cell, 11...
Upper surface electrode, 12... Lower surface electrode, 20a...
...lower board, 20b...upper board, 20c...
...Connection board, 21a...Lower printed wiring, 21b...Upper printed wiring, 22...
... U-shaped cut, 23 ... Broken line part, 2
4...Protrusion for lead terminal, 30...Metal substrate, 31...Legs, 40...Conductive member, 50a...Bottom Side time display window, 50b...
...Upper time display window, 60...Solar cell window,
70...Diode, 80...Resistor.

Claims (1)

[Scope of utility model registration request] A lower substrate having printed wiring for electrical connection with the lower surface electrode of the solar cell and an upper substrate having printed wiring for electrical connection with the upper surface electrode of the solar cell are integrally formed by a connecting substrate, The lower electrode of the solar cell is fixed to the printed wiring of the side substrate for electrical connection, and the upper substrate is superimposed on the lower substrate by bending it at the connecting substrate, and the upper electrode of the solar cell is fixed to the printed wiring of the side substrate. is fixed and electrically connected to the printed wiring of the upper substrate, and the solar cell is sandwiched between the lower substrate and the upper substrate, and the solar cell receives light from the solar cell window provided on the upper substrate. A solar cell substrate structure characterized in that the connection substrate is provided with a lead terminal portion with an exposed surface and for connection to a module.