WO2020126614A1

WO2020126614A1 - Method and device for reducing the potentially induced degradation of solar cells

Info

Publication number: WO2020126614A1
Application number: PCT/EP2019/084217
Authority: WO
Inventors: Bart Elger PIETERS; Andreas Gerber
Original assignee: Forschungszentrum Jülich GmbH
Priority date: 2018-12-20
Filing date: 2019-12-09
Publication date: 2020-06-25
Also published as: EP3900181A1; DE102018222585A1

Abstract

The invention relates to a solar module for generating an electric current, comprising a plurality of photovoltaic cells (13) which are electrically connected together, wherein one photovoltaic cell (13) has two electrodes, and a material, in which free charge carriers can be generated by an electromagnetic wave, is located between the two electrodes. The solar module also comprises one or more components (10) adjoining photovoltaic cells (13). The invention is characterized in that an electric device (15, 30, 31) is provided, by means of which an electric potential difference between one side of a photovoltaic cell (13) and an adjoining component (10) is reduced when generating an electric current. The invention additionally relates to a method for operating the solar module. By using the invention, an efficient solar module with a long service life can be provided.

Description

Method and device for reducing the potential induced degradation of solar cells

The invention relates to a solar module and a method for operating the solar module.

A solar module consists of a plurality of photovoltaic cells. A photovoltaic cell can convert radiation energy, in particular light, into electrical energy. A photovoltaic cell, also called a solar cell, comprises a material, for example a semiconductor material, in which free charge carriers are generated by electromagnetic radiation. Two electrodes are adjacent to the material mentioned. The named material is then between the two electrodes. For example, an electric field, such as an internal electric field of a pn-type semiconductor, leads the free charge carriers generated out of the material mentioned.

The electrical current thus generated can be supplied to an electrical consumer via the adjacent electrodes.

The photovoltaic cells of a solar module are electrically connected to each other, usually in series. The photovoltaic cells of a solar module can be protected, for example, by a glass cover. Alternatively or in addition, one or more other protective layers, for example made of plastic, may be present. A solar module can include an anti-reflective layer. For reasons of protection, a solar module can include a frame. The frame can be electrically grounded.

During the operation of a solar module, one side of the photovoltaic cells is at a positive potential and an opposite side of the photovoltaic cells is at a negative potential. Adjacent components such as glass, other layers or frames are at zero potential or close to zero potential. Potential differences therefore occur during operation between surfaces of photovoltaic cells and adjoining components. Such potential differences allow ions, for example Na ⁺ ions, to migrate from the named components to the solar cells and harm them. This negative effect, which is called potential-induced or voltage-related degradation, can cause large power losses.

It is known from WO 2015/191699 A1 to arrange an electrically insulating material between the frame of a solar module and photovoltaic cells of the solar module in order to avoid potential-induced degradation.

From US 7,554,031 B2 it is known to apply a conductive layer to a dielectric passivation layer of a solar cell, in order to avoid potential-induced degradation. Since the conductive layer is to be applied on the incident side for light, the incidence of light is reduced by the conductive layer and thus the efficiency of the solar module.

It is an object of the invention to create powerful and long-lasting solar modules.

The object is achieved by a solar module according to claim 1 and by a method according to the independent claim. Advantageous refinements result from the claims which refer back to them in each case.

To solve the problem, a solar module for generating electrical power is provided, which comprises a plurality of photovoltaic cells. Each module can comprise more than 10 photovoltaic cells, for example more than 50 photovoltaic cells.

The photovoltaic cells of a solar module are electrically connected to one another, preferably in series, so that a solar module can provide a higher voltage compared to the voltage that a single photovoltaic cell can generate.

A photovoltaic cell has two electrodes. Between the two electrodes is a material in which free charge carriers can be generated by an electromagnetic wave. The material can be crystalline, polycrystalline or amorphous silicon, for example. The material can be a II IV semiconductor such as GaAs. The material can be an Il-VI semiconductor such as CdTe. The material can be an III-III semiconductor, such as copper indium gallium diselenide. The material can be on based on organic hydrocarbon compounds or organic dyes. The material can be doped.

The electrodes consist of an electrically conductive material, for example of metal such as copper or silver. An electrode is transparent on a light-incident side and consists, for example, of indium tin oxide, fluorine-tin oxide, aluminum-zinc oxide or antimony-tin oxide.

Components such as a glass pane or a layer made of plastic adjoin photovoltaic cells.

There is an electrical device by means of which an electrical potential difference between one side of a photovoltaic cell and an adjoining component is reduced during the generation of electrical current. If a component borders on the side of a solar cell that is at negative potential during power generation, then this adjacent component is also brought to a negative potential, for example by the electrical device, so that the potential difference is reduced. If a component borders on the side of a solar cell that is at a positive potential during power generation, then this adjoining component is also brought to a positive potential by the electrical device, for example, in such a way that the potential difference is reduced.

The potential equalization prevents the solar module from being damaged by potential-induced degradation. This improves the longevity of a solar module. The electrical power that has to be used for this is extremely low. Power losses caused by this are therefore negligibly small. The technical effort can be kept low.

The electrical device is preferably set up such that the required electrical power is provided by the solar module during operation. Then the solar module can be operated independently.

The adjacent component can be a glass pane. The glass pane can rest directly on electrodes of the photovoltaic cells. The glass pane can be made with electrodes be glued. There may be at least one intermediate layer between electrodes and glass pane.

In a technically simple embodiment, the electrical device comprises one or protective contacts. Each protective contact can rest on the adjacent component. Each protective contact can be glued to adjacent components. The adjoining component can be located between two protective contacts. Two protective contacts of the electrical device can rest on opposite sides of the adjacent component, for example on a glass pane. The one or more protective contacts can be attached to a glass pane, for example.

One or more protective contacts of the electrical device can be frame-like, for example rectangular or square, in order to suitably reduce a potential difference without excessively hindering the incidence of an electromagnetic wave.

One or more protective contacts of the electrical device preferably adjoin the edge of the solar module in order to further reduce a potential difference in a suitable manner without excessively hindering the incidence of an electromagnetic wave. One or more protective contacts of the electrical device then run close to the edge of a solar module and generally parallel to the edge of the solar module. The distance to a frame or edge of a solar module and a protective contact of the electrical device can then be less than 5 cm, preferably less than 3 cm, particularly preferably less than 1 cm.

The one or more protective contacts can run around the solar cells when viewed from the top of the solar cells.

One or more protective contacts of the electrical device can consist of a transparent, electrically conductive material in order to further reduce power losses. One or more protective contacts of the electrical device can consist of a metal.

At least one protective contact of the electrical device is preferably connected to an electrical resistance. In the installed state of the solar module, this is was connected to earth, i.e. grounded. The electrical resistance can be connected to an electrically conductive frame of the solar module if it is intended to ground the electrically conductive frame in the installed state. A risk to persons due to an electrical current through a protective contact is thus avoided.

The resistor may include a grounding means at one end, such as a means such as an electrical connector or an electrical socket, for connecting the resistor to ground through an electrical connector. But it can also be an electrical cable that can be connected with its free end, for example with a clamp connection.

The electrical resistance can be more than 1 kQ, preferably more than 10 kQ, particularly preferably more than 100 kQ.

In one embodiment, the solar module comprises a frame which, in the installed state, can be grounded for protection reasons, that is to say it is then connected to ground. To this end, the frame may include means for grounding the frame. This device is, for example, an electrical plug or an electrical socket that can be connected to a ground or to ground by an electrical plug connection. But it can also be an electrical cable that can be connected with a free end connection with a clamp connection.

The invention particularly relates to a plurality of solar modules that are electrically connected in series. In this case in particular, solar modules can be damaged by the degradation, which is reliably avoided by the invention with little technical effort and with little loss of power.

During operation, electromagnetic radiation, in particular light, strikes the solar module, as a result of which the solar module generates an electrical current. During the generation of the electrical current, the electrical device approaches the electrical potential of a component to the electrical potential on which an adjoining side of the photovoltaic cell is located. The adjoining side of the photovoltaic cell is particularly at negative potential, since this case is particularly problematic. The invention is explained in more detail below with reference to exemplary embodiments and the attached FIGS. 1 to 3, without the invention being restricted thereby.

Show it:

Fig. 1: Cross section of an earthed solar module according to the prior art with posible Chen leakage currents;

2: cross section of an earthed solar module with protective contacts according to the invention for reducing the potential-induced degradation;

Fig. 3: supervision of a solar module with protective contact according to the invention.

FIG. 1 shows a section of a lateral cross section of a solar module in the area of its frame 14 with photovoltaic cells 13. The photovoltaic cells 13 are embedded in an ethylene-vinyl acetate layer 12. The front of the solar module is covered by a glass plate 10. A rear wall 11 is applied to the rear. The frame 14 is electrically grounded.

In Figure 1, two possible paths for leakage currents are shown as an example, which can cause a potential-induced degradation. A first possible leakage current path 20 can run from photovoltaic cells 13 through the ethylene vinyl acetate layer 12 and through the glass plate 10 along the top of the glass plate 10 to the frame 14 and then to ground. A second possible leakage current path 21 can migrate from the photovoltaic cells 13 through the ethylene vinyl acetate layer 12 along the underside of the glass plate 10 and from here along the underside of the glass plate 10 to the frame 14 and then to ground.

FIG. 2 also shows a section of a lateral cross section of a solar module in the region of the frame 14 of the solar module, corresponding to FIG. 1. The solar module comprises photovoltaic cells 13 which are embedded in an ethylene-vinyl acetate layer 12. There is a glass plate 10 on the front and a rear wall 11 on the back. The frame 14 also has an earth connection. In FIG. 2, two possibilities for the attachment of protective contacts 15 according to the invention are shown by way of example, one protective contact 15 for preventing or reducing a leakage current 20, 21 from FIG. 1 being arranged in each case. According to the invention, protective contacts 15 are arranged in the region of the frame 14, to each of which a protective contact line 30, 31 is connected. To the protective contacts 15, a potential is applied via the protective contact lines 30, 31, which is close to the potential of the adjacent side of the solar module and less close to the potential of the frame 14. Leakage currents 20, 21 can thereby be avoided. Leakage currents 22, 23 can occur which flow from protective contacts 15 to frame 14. Such leakage currents 22, 23, however, are negligibly small and harmless.

FIG. 3 shows a top view of a solar module with a rectangular protective contact 15 arranged according to the invention on the front side of a glass pane. There can also be an identical electrical protective contact on the back of the glass pane. In this exemplary embodiment, the one or more protective contacts 15 are arranged such that they run around the photovoltaic cells 13. Such protective contacts 15 can be arranged both above and below a layer of the solar module or only above or only below the layer. In particular, an external protective contact 15 is connected to an electrical resistance (not shown in FIG. 3). This electrical resistance is grounded during operation of the solar cell.

Damage to solar cells 13 in solar modules can be avoided by the invention. A potential which is closer to the adjacent potential of the photovoltaic cells 13 than to the potential of the frame 14 is applied to one or more protective contacts 15 during the generation of electricity.

Reference symbol list:

10: Glass plate on the front

11: rear wall of the solar module

12: ethylene vinyl acetate layer (EVA)

13: photovoltaic cell

14: frame

15: protective contact 20: leakage current path

21: leakage current path

22: leakage current path

23: Leakage current path 30: protective contact line

31: protective contact line

Claims

1. Solar module for generating electrical current comprising a plurality of

photovoltaic cells (13) which are electrically connected to one another, a photovoltaic cell having two electrodes and a material between the two electrodes in which free charge carriers can be generated by an electromagnetic wave, and at least one to photovoltaic cells ( 13) adjoining the component (10, 12), characterized in that an electrical device (15, 30, 31) is present, by means of which an electrical potential difference between one side of a photovoltaic cell (13) and the one during generation of electrical current adjacent component (10) is reduced.

2. Solar module according to claim 1, characterized in that the adjoining component is a glass pane (10).

3. Solar module according to one of the preceding claims, characterized in that the electrical device comprises one or more protective contacts (15) in the adjoining component (10).

4. Solar module according to the preceding claim, characterized in that one or more protective contacts (15) of the electrical device are frame-like.

5. Solar module according to one of the two preceding claims, characterized

is characterized in that one or more protective contacts (15) of the electrical device borders on the edge of the solar module and / or on a frame (14) of the solar module.

6. Solar module according to one of the three preceding claims, characterized in that one or more protective contacts (15) of the electrical device are connected to an electrical resistor.

7. Solar module according to the preceding claim, characterized in that the electrical resistance is more than 1 kQ, preferably more than 10 kQ, particularly preferably more than 100 kQ.

8. Solar module according to one of the preceding claims, characterized in that the solar module comprises a frame (14) and a device for grounding the frame.

9. The method for operating a solar module according to one of the preceding claims, characterized in that electromagnetic radiation strikes the solar module and the solar module thereby generates an electrical current and during the generation of the electrical current the electrical device (15, 30 , 31) the electrical potential of a component approximates the electrical potential on which an adjoining side of the photovoltaic cell is located.

10. The method according to the preceding claim, characterized in that the adjoining side of the photovoltaic cell (13) is at negative potential.