EP2465175A1

EP2465175A1 - Solar cell

Info

Publication number: EP2465175A1
Application number: EP10737920A
Authority: EP
Inventors: Wolfgang Volz; Gregor Kron; Tobias Mildenstein
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2009-08-10
Filing date: 2010-08-03
Publication date: 2012-06-20
Also published as: WO2011018390A1; WO2011018390A9; DE102009028393A1; US20120199197A1; CN102576741A

Abstract

The invention relates to a solar cell having a flat cell substrate (1) that is transparent in the spectral range of visible light and at least one partial range of the infrared spectral range, and a cell construction (5) disposed on a surface of the same, wherein a bifunctional or multifunctional layer (3) is applied to the surface supporting the cell construction, said layer being transparent in the range of visible light and having an infrared reflecting function and having a contacting function.

Description

description

title

solar cell

The invention relates to a solar cell with a planar cell substrate, which is transparent in the spectral range of visible light and at least a portion of the infrared spectral range, and a cell structure arranged on a surface thereof.

State of the art

Photovoltaics is one of the most dynamic areas of energy technology and is gaining increasing economic importance. The development of multi-faceted configurations of solar cells and their technological refinement have contributed significantly to this in recent years. An essential development line relates to the provision of optimized carrier or substrate structures which have advantageous optical and thermal properties in terms of a high energy yield and are technically easy and inexpensive to implement.

As a substrate for constructing various types of solar cells, glass having a transparent conductive layer, often a doped oxide layer (TCO), is usually used as a front contact. This design is technologically simple and inexpensive to implement, and can rely on long-established and readily available materials, and is largely transparent in the optical as well as for much of the infrared (IR) spectral range. IR radiation has z. For example, for crystalline silicon from about 1100 nm, there is not enough energy to create electron-hole pairs and thus contribute to the photocurrent. Therefore, this type of radiation does not contribute positively

Efficiency of the solar cell, but leads to additional heating and thus deterioration in efficiency. For modules made of crystalline Si solar cells, the efficiency reduction is about 0.5% / ° C, in the case of thin-film cells 0.2 - 0.3% / ° C. An already known approach is to reflect the IR radiation so that it does not penetrate into the solar cell and in this way can not lead to any additional heating.

A configuration following this approach is described in EP 0 632 507 A2 in various variants. An IR-reflecting arrangement comprising a plurality of protective layers suppresses low-order reflections and thus reflects spectral bands which are beyond the short- and long-wave limits of the wavelength range that the solar cell can use for the opto-electrical conversion. The structures described are flexible in their parameters adjustable, but relatively expensive to implement.

Disclosure of the invention

The invention is therefore based on the object to provide a solar cell with a simplified structure and reduced manufacturing costs, the construction nevertheless ensures adequate shielding of unusable parts of the incident sunlight.

This object is achieved by a solar cell having the features of claim 1. Advantageous embodiments of the inventive concept are the subject of the dependent claims.

The invention includes the essential idea of deliberately departing from the approach underlying EP 0 632 507 A2 to specify the simplest possible substrate structure, the production of which only few steps required. It further includes the idea of realizing for this purpose various functions which the substrate structure must realize in relation to the actual cell structure, in a meaningful way in as few as possible provided on the substrate layers. This finally results in the essential idea that only on the surface of the cell substrate carrying the cell structure is a bi-or multifunctional layer applied, which is transparent in the region of visible light and has an infrared-reflecting and a contacting function. The advantage of the invention described lies in the combination of two layers, the conductive front contact and the IR reflection layer, to form a bi-functional layer. This construction results in an improved optical transmission of the usable solar radiation. In addition, the structure simplifies the manufacture and leads to a cost reduction, since only a coating process and a coating material is necessary. A further advantage lies in the good thermal conductivity and the "inner layer" of the conductive reflection layer, which allows the solar cell to dissipate heat without radiation, otherwise the IR radiation would also reflect due to the cell temperature and thus lead to a heating of the cell This would be the case if the IR reflection layer were located on the outside, that is to say in the position of use of the sun facing side, because of the lower heat absorption due to reflected IR radiation, the efficiency of the module initially improves

Minimized average lower temperature, which in turn leads to an extended life of the module.

An advantageous embodiment in the sense of the above-mentioned aim of minimizing the number of layers provides that the bi- or multifunctional layer has a high electrical conductivity. In particular, she has one

Sheet resistance of less than 15 Ω / D in order to serve as the (only) front side contacting layer of the solar cell without any functional limitations. In a technologically proven and cost-effective manner, a glass substrate is used as substrate in a further embodiment of the invention. Concrete glass compositions have long been established in the photovoltaic art and are useful in the practice of the present invention. With regard to the bi- or multifunctional coating essential to the invention, dyeing for filtering out IR radiation components by means of absorption can be dispensed with, ie "clear glass." In principle, substrate materials also include high-temperature-resistant transparent plastics, quartz glass, and other proven transparent support materials into consideration.

The above-mentioned goal is particularly taken into account when the bi-or multifunctional layer is provided as the only infrared-reflecting agent and as the only front-side contacting layer of the solar cell. To some extent, however, this goal is already achieved if the layer exclusively fulfills only one of these two functions, while an additional layer is provided for the complete fulfillment of the respective remaining function. In the sense of the above-mentioned advantage of improved optical transmission or low absorption of the usable sunlight in the cell, the bi- or multifunctional layer in the spectral range of visible light has an absorption coefficient below a threshold, in particular below 20%. Depending on the performance requirements and physical parameters of the actual solar cell, however, another value can also be specified.

In order to achieve the most efficient rejection of the harmful IR radiation, in a preferred embodiment of the invention, the bi-or multifunctional layer has a reflection coefficient above a predetermined threshold value, in particular at 1100 nm and more than 50%, in a subarea of the infrared spectral range. , Has. Even with respect to these values, depending on the specific cell structure and the overall structure modifications possible and possibly useful.

The complex functionality of the proposed substrate coating can be achieved in an expedient and reliable manner when the bi- or multifunctional layer comprises metal particles, in particular silver particles having a mean grain size in the nanometer or micrometer range, in particular 100 nm or less. In addition to silver, other metals are suitable, such as - depending on the other properties of the module structure - gold or copper or alloys of the metals mentioned. It is also possible to deviate from the said preferred grain size upper limit, and it may also be advantageous to use the intercalation material with a predetermined particle size distribution. The single figure shows schematically in a cross-sectional representation the structure of a solar cell 1 according to the invention, with a glass substrate 1, a bifunctional (electrically conductive and IR-reflecting) layer 3 and a solar cell Abau 5, in use in this order of a symbolized by the arrow A solar radiation exposed. The bifunctional layer 3, z. B. consisting of Ag nanoparticles, is in thermal contact with the glass and the actual solar cell and has a good thermal conductivity.

The incident IR-TeM of the solar radiation is reflected by the reflection layer and thus does not contribute to the heating of the solar cell. In addition, the layer takes over the function of the front contact, wherein no additional TCO or comparable layer is necessary, which would reduce the optical transmission and thus deteriorate the efficiency of the solar cell. Due to the good conductivity, the heat of the solar cells is passed through the reflective layer into the substrate, which emits energy according to its emissivity and temperature.

Claims

claims

1. A solar cell, with a planar cell substrate, which is transparent in the spectral range of visible light and at least a portion of the infrared spectral range, and a cell structure arranged on a surface thereof, wherein on the surface of the cell substrate carrying the cell structure a bi- or multi-functional Layer is transparent, which is transparent in the visible light region and has an infrared-reflecting and a contacting function.

2. Solar cell according to claim 1, wherein the bi- or multi-functional layer is electrically conductive, with a sheet resistance below a predetermined threshold, in particular below 15 Ω / D.

3. A solar cell according to claim 1 or 2, wherein the substrate is or comprises a glass substrate.

4. Solar cell according to one of the preceding claims, wherein the bi- or multifunctional layer is provided as the only infrared-reflecting means of the solar cell.

5. Solar cell according to one of the preceding claims, wherein the bi- or multifunctional layer is provided as the only front-side contacting layer of the solar cell.

6. Solar cell according to one of the preceding claims, wherein the bi- multi-functional layer is thermally conductive and in Wärmeleitkontakt to

Cell substrate and / or cell structure stands.

7. Solar cell according to one of the preceding claims, wherein the bi- or multi-functional layer in the spectral range of visible light Absorption coefficient below a predetermined threshold, in particular below 20%, has.

8. Solar cell according to one of the preceding claims, wherein the bi- or multi-functional layer in a partial region of the infrared spectral range has a reflection coefficient above a predetermined threshold, in particular at 1100 nm and more above 50%.

9. Solar cell according to one of the preceding claims, wherein the bi- or multi-functional layer metal particles, in particular silver particles having a mean grain size in the nanometer or micrometer range, in particular of 100 nm or less, having.