Batteries: thermoelectric and photoelectric – Photoelectric – Panel or array
Reexamination Certificate
1999-05-13
2001-06-19
Robinson, Ellis (Department: 1772)
Batteries: thermoelectric and photoelectric
Photoelectric
Panel or array
C257S446000, C257S466000
Reexamination Certificate
active
06248948
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a solar cell module and a method of producing it. More specifically, the invention relates to a solar cell module which can be produced at a low cost, which shows a smaller energy conversion efficiency degradation even when the solar cell module is partly shaded and which is not damaged even when maintained in such state for a long time, and a method of producing such solar cell module. The present invention also relates to a solar cell module that can effectively exhibit a high energy conversion efficiency when installed on a curved surface, and a method of producing such solar cell module.
2. Related Background Art
Solar cells have been widely developed and are starting to be introduced for use in the home, as the environmentally acceptable clean power source. Ordinary electric appliances are usually driven with an alternating current of 100 V. On the other hand, the output of a solar cell is a direct current, and an inverter has to be used in order to obtain an alternating current. In such a case the inverter cannot operate efficiently unless the output of the solar cell is at least 100 V. Also when the electric power is stored in a secondary battery, the DC output can be directly used, but the secondary battery is usually used at 12 V to 24 V.
However, a unit cell of a solar cell can only provide an output voltage of 0.5 to 0.6 V, also a unit cell of an amorphous silicon solar cell of a relatively high output voltage can only provide an output voltage of 0.7 to 0.9 V alone, and the tandem cell of plural junctions stacked can only provide an output voltage of about 2 V at maximum. For this reason, the solar cell is usually used as a module in which plural unit cells are connected in series. Such formation of the module by series connection of the unit cells of the solar cell also provides an advantage of reducing the current in the module, thereby remarkably lowering the power loss resulting from electric resistance in the wiring part.
However, during the use of the module with the unit cells connected in series, there may generate a situation where the shade of a wood or a building falls on a certain unit cell of the unit cells constituting the module, whereby only the output of the certain unit cell extremely drops. Such a situation is called a “partial shade state”. In such a partial shade state, the output voltage of the entire module dramatically drops, and in some cases the shaded unit cell merely functions as a load to cause heat generation or is damaged by a strong reverse bias voltage. In this regard, it is known to connect a small diode which is called a bypass diode to a solar cell element (unit cell) in parallel and in an opposite direction thereto, thereby reducing the influence of such a partially shaded state.
FIG. 4
shows the working principle of such a bypass diode, wherein unit solar cells
301
to
304
of the solar cell are connected in series and further connected to an external load
305
. In a normal state under irradiation with sunlight
306
, there is generated an output voltage equal to the sum of the output voltages of the unit cells
301
to
304
(in
FIG. 4
, reference character A indicates a terminal at a negative side, and B indicates a terminal at a positive side). However, when the shade of an object
307
falls, for example, on the unit cell
303
, the unit cell
303
substantially functions as a load of an extremely high resistance, whereby the output current of the module is reduced and the output voltage is extremely lowered. In addition, the unit cell
303
receives, in the opposite direction, the sum of the output voltages of the unit cells
301
,
302
and
304
, whereby such reverse bias voltage causes abnormal heat generation in the unit cell
303
or damages the unit cell
303
by the reverse electric field.
On the other hand, in the case of providing a bypass diode
303
′ with the unit cell
303
, the unit cell
303
is short circuited, whereby an originally intended current substantially flows in the entire circuit and the unit cell
303
can be protected from the reverse electric field. When the unit cell
303
functions in the normal state, the bypass diode
303
′ is reversely biased, whereby little leak current flows and the function of the module is not affected. The bypass diodes
301
′ to
304
′ are provided for the unit cells
301
to
304
of the solar cell, respectively, thereby causing damage by the reverse electric field in a unit cell unit.
However, such bypass diodes are required in the same number as that of the unit cells, and therefore the cost and complexity of the wiring step for this purpose is appreciable. For example, the Japanese Patent Application Laid-Open No. 3-24768 proposes that the bypass diode is integrally formed with the unit cell. In the prior art, as shown in
FIGS. 9
,
10
,
11
A and
11
B, n-type diffusion regions are formed on both sides of a p-type substrate, and one of such diffusion regions is utilized as the bypass diode. In these drawings, reference character
20
indicates a p-type silicon substrate;
21
and
22
, n-type diffusion layers;
23
and
24
, electrodes; SC, a unit cell; BD, a bypass diode;
1
,
2
and
3
, unit cells; A and B, bypass diodes; C, a bypass diode; and
25
,
26
,
27
and
28
, lead wires. Such a configuration, however, has drawbacks such as requiring a complex series connection step and also requiring one external diode per module. For this reason, the above-mentioned patent application also proposes a method of integrally forming an independent bypass diode in the substrate, as shown in
FIGS. 12A
,
12
B,
13
A and
13
B. In these drawings, reference characters
61
and
101
indicate p-type silicon substrates;
62
and
102
, n
+
-type diffusion layers;
63
and
103
, n-type diffusion regions;
64
and
104
, p-type diffusion layers;
65
and
105
, oxide films;
66
and
106
, oxidation preventing films;
67
and
107
, surface electrodes;
68
and
108
, back surface electrodes; and
109
, a junction short circuit portion. This configuration certainly simplifies the series connection step, but requires an additional semiconductor step for incorporating the diode into the substrate, so that this configuration cannot reduce the total manufacturing cost of the solar cell module.
SUMMARY OF THE INVENTION
In consideration of the foregoing, the object of the present invention is to provide a solar cell module of a novel configuration which is capable of minimizing the reduction of the module output without damage in the unit cells even in the partial shade state and and which is not complex in the semiconductor step or in the series connection step, as compared to a solar cell module. without such countermeasure, and a method of producing such a solar cell module.
According to the view of the present inventors, the structure shown in
FIG. 9
is rather advantageous in the prior art in terms of simplifying the semiconductor step. Namely, the n-type diffusion layers (one being used for the light-receiving region, the other being used for the bypass diode) on both sides of the p-type substrate can be prepared in one step. However, the n-type diffusion layer for the bypass diode has to be thereafter removed except for a necessary area. Also as pointed out in the above-mentioned patent application, it is not easy to form the series connection bridging the top side and the bottom side of the substrates as shown in
FIGS. 11A and 11B
.
The present inventors have conceived to form the light-receiving portion of the solar cell element and the bypass diode on the same side of the substrate. Such a configuration allows for series connection from only one side of the substrate. The unit cell of such a structure, if prepared by a simple method, will provide a countermeasure against the partial shade state at the lowest cost in total.
The present invention provides a solar cell module comprising a plurality of unit cells connected in series, each of the uni
Iwasaki Yukiko
Nakagawa Katsumi
Nishida Shoji
Canon Kabushiki Kaisha
Fitzpatrick ,Cella, Harper & Scinto
Miggins Michael C.
Robinson Ellis
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