WO2023006833A1 - Multi-core terminal connector for photovoltaic modules - Google Patents

Abstract

The invention relates to a photovoltaic module (20) having a plurality of solar cells (10) and having at least one multi-core terminal connector for discharging an electric current from a plurality of solar cells (10) within a photovoltaic module (20). The terminal connector comprises a bundle (100) of wires, wherein the wires form a braided bundle (110) or a twisted bundle (120) or an untwisted bundle (140). The bundle (100) is designed to provide the following electrical connection: a component connector (100c) which has contact with an electric component (60) of the photovoltaic module (20). A cross-connector (15b) is designed as a current busbar between a cell connector (100a), which has contact with at least one solar cell (10), and the component connector (100c) in order to discharge the current from the solar cells (10).

Description

MULTI-WIRE CONNECTOR FOR

PHOTOVOLTAIC MODULES

The present invention relates to a photovoltaic module with a multi-wire connection connector for deriving a current from one or more solar cells within the photovoltaic module and a method for electrically contacting solar cells and in particular to multi-wire connection connectors as strain relief elements for bypass elements such as diodes.

BACKGROUND

Photovoltaic modules are often exposed to extreme temperature fluctuations during use. As a result, thermal stresses of considerable magnitude can damage electrical connections within the photovoltaic module over time or even interrupt them completely. In the worst case, this can mean that the entire photovoltaic module can only be used insufficiently due to interrupted electrical connections. There is therefore a need for connectors within a photovoltaic module that can reliably withstand greater thermal stresses.

BRIEF DESCRIPTION OF THE INVENTION

The above-mentioned object is achieved by a photovoltaic module according to claim 1 and a method for contacting solar cells according to claim 8. The dependent claims relate to advantageous developments of the subject matter of the independent claims.

The present invention relates to photovoltaic modules with a plurality of solar cells and at least one multi-wire connection connector for deriving an electric current from a plurality of solar cells within a photovoltaic module. The terminal connector comprises a bundle of wires, the wires forming a braided bundle or a twisted bundle or an untwisted bundle. The bundle is configured to provide the following electrical connection: a component connector having contact to an electrical component of the photovoltaic module. A cross-connector for deriving the current from the solar cells is designed as a current busbar between a cell connector, which has a contact to at least one solar cell, and the component connector.

The bundle may be configured to also provide at least one of the following electrical connections:

- a cell connector that has a direct contact to at least one solar cell,

- A cross-connector which has a direct contact to a cell connector.

It goes without saying that the connection connector is to be dimensioned in such a way that sufficient current can be derived and the connection connector can be accommodated in a photovoltaic module. The connection connector is therefore advantageously not too thick, but bendable in order to be able to lay the electrical connection flexibly.

The electrical component is accommodated, for example, in a junction box from where, for example, the entire current of the photovoltaic module is derived. The electrical component can, for example, switch off or bypass individual solar cells or the entire photovoltaic module automatically or in a targeted manner. It goes without saying that the connection connector is intended to be used within the photovoltaic module and not as an external cable which connects the entire photovoltaic module. Optionally, the wires in the bundle are held together by braiding or weaving or gluing or welding or by holding means. There can be a force-fit or a form-fit connection between the wires. The holding means can, for example, clamps or ring-shaped Include elements that hold the wires together (e.g., mechanical clamps, ferrules, connections by crimping, etc.)

Optionally, the bundle of wires forms a braided flat band in a cross section perpendicular to a direction of flow. The braided band can be as flat as possible so as not to increase the thickness of the photovoltaic module. In addition, it can be made as wide as possible in order to enable a sufficient flow of current.

Optionally, the wires within the bundle are at least partially electrically isolated from one another or electrically connected to one another. It will be appreciated that the wires may contact adjacent wires at multiple points along their length, which contact is either electrically conductive or electrically isolated (e.g., where the individual wires are themselves insulated). In addition, it is possible for the entire bundle to be electrically insulated, for example by providing a corresponding coating or sheathing that reliably insulates the current path.

Optionally, at least some of the wires of the bundle have a coating of a soft solder and/or a conductive plastic. The coating using a soft solder can be useful in order to enable automatic contacting of various connectors by means of local heating to the melting temperature of the solder. This makes it possible, for example, for the connection connectors to be placed one on top of the other and a reliable electrical connection to be established through targeted heat input. The same effect can be achieved with the conductive plastic, which when melted thermally can also bond and thus create an electrical connection between different connectors.

Optionally, the wires are made of copper or have a copper core. Other possible materials are aluminum, carbon nanotubes, etc. The use of copper offers the advantage that copper has a high level of conductivity and copper wires can also be braided easily, resulting in flat connectors braided or twisted without excessive increase in thickness perpendicular to the module surface.

Exemplary embodiments also relate to a photovoltaic module with a number of solar cells and at least one multi-wire connection connector, as previously defined. The photovoltaic module can, for example, have various multi-wire connection connectors that connect, for example, adjacent solar cells in series to form a solar cell chain (these are the cell connectors). In addition, cross-connectors can be designed as multi-wire connection connectors in order to collect the current from several solar cell strings. The various multi-core connectors can be of the same type (e.g. as braided ribbons) or of different types. Thus, multi-wire terminals may interface with other terminals formed differently (e.g. forming twisted or untwisted bundles of wires). Likewise, the connectors can be connected to conventional busbars or conventional wires (or conductive pastes).

Optionally, the photovoltaic module has at least one bypass element for dissipating an electrical overvoltage as an electrical component. The at least one bypass element can be electrically contacted by the component connector with the bundle of wires. The bypass element can, for example, comprise a diode or another electrical component which, for example, establishes an electrical connection above a certain voltage value (e.g. in the event of a breakdown voltage) in order to protect the module in this way. This can be advantageous, for example, if the module is partially shaded. In the solar cells that are not exposed to sunlight, the electrical resistance will increase due to the low density of charge carriers, which will result in a high voltage drop. In order to avoid damage, however, it is important that the bypass elements can efficiently dissipate such overvoltages.

Optionally, the photovoltaic module includes a (conventional) busbar for deriving the current from the solar cells and the component connector is seen between the bypass element and the busbar (e.g. the current can routed section by section through the conductor rail). As a result, mechanical relief for the bypass element can be achieved. The mechanical stresses can occur, for example, as a result of the considerable heat input and endanger or damage the electrical connections. With conventional photovoltaic modules, there is always a loss of contact with the bypass element, which ultimately leads to damage. As stated, exemplary embodiments reliably avoid such damage. In particular, thermally induced stresses or mechanical stresses can be reduced in different directions (e.g. strain relief, transverse relief) by appropriately aligning the connectors.

Optionally, a multi-core cross connector can already be connected directly to the bypass element (e.g. the diode). A component connector is not absolutely necessary.

A particular advantage of the connection connectors according to exemplary embodiments is that the connection connectors can be laid flexibly during manufacture without being exposed to the risk of the lines breaking. At the same time, a high current density can be made possible by forming the terminal connectors, for example, as a narrow, wider band.

Exemplary embodiments also relate to a method for making electrical contact with solar cells of a photovoltaic module. The procedure includes:

providing a bundle of wires, the wires in the bundle being braided or twisted or untwisted; and

Forming at least one of the following electrical connections using the provided bundle of wires: - a cell connector through a contact to at least one solar cell,

- a component connector through a contact to an electrical component of the photovoltaic module, wherein a cross connector for deriving the current from the solar cells is formed as a current busbar between the cell connector and component connector (100c). The bundle of wires can include any number of wires. For example, the bundle can have 2, 3 or at least 5 or at least 10 or at least 20 wires. At least a portion of the wires of the bundle may have a coating of solder and/or conductive plastic, and the method may optionally further comprise: locally heating the bundle of wires to electrically connect the wires to each other or to a current collection device.

BRIEF DESCRIPTION OF THE FIGURES

Embodiments of the present invention are described in detail in the following detailed description and the accompanying drawings, which, however, should not be taken to limit the disclosure to the specific embodiments, but are for explanation and understanding only.

1A shows connection connectors within photovoltaic modules according to exemplary embodiments.

1B shows an example of a photovoltaic module with the multiplicity of solar cells. 2-9 show exemplary embodiments in which the cross-connectors and/or cell connectors are designed according to exemplary embodiments or conventionally.

FIG. 10 shows an exemplary embodiment for a possible contacting of an electrical component within the junction box of a photovoltaic module.

FIG. 11 schematically shows a flowchart for a method for electrically contacting solar cells of a photovoltaic module. DETAILED DESCRIPTION

1A shows, by way of example, different possibilities for using connection connectors according to exemplary embodiments within a photovoltaic module 20 . A photovoltaic module 20 is shown as an example in FIG. The photovoltaic module 20 comprises a plurality of solar cells 10 and a connection box 40, with a connection line 50 being provided in order to route the current away from the connection box 40 and to feed it into a public power grid, for example. The multi-wire terminal connectors 100 cannot be seen in FIG. 1B. 1A shows further details of the photovoltaic module 20. For example, the solar cells 10 are arranged in the form of solar cell rows 10a and 10b. The solar cells 10 within each row 10a, 10b, . The cell connectors 100a, 15a are electrically connected to cross-connectors 100b, 15b, which collect the current from a plurality of solar cell rows 10a, 10b and transport it to a junction box 40. A bypass element 60 (or other electrical components such as switches), for example, is accommodated within a junction box 40 and is electrically contacted by a component connector 100c, 15c.

However, the exemplary bypass element 60 does not have to be in the junction box 40; it can also be formed in other positions in the photovoltaic module 20. The exemplary bypass element 60 can also be in the form of a laminated component, for example. In particular, it is intended to switch off individual cells or subgroups of solar cells in the event of shadowing or defects in order to avoid damage to the module.

The cell connectors 15a, 100a, the cross-connectors 15b, 100b and the component connectors 15c, 100c can each be conventional (then bear the reference number 15) or be designed according to exemplary embodiments (then bear the reference symbol IOO). The various possibilities are specifically described in the following figures.

FIG. 2 shows an exemplary embodiment in which the cross-connectors 110b are designed as a braided bundle, which is electrically contacted by conventional cell connectors 15a. The conventional cell connectors 15a are designed, for example, as so-called busbars or by wires. In the exemplary embodiment shown, a plurality of cell connectors 15a are formed on a surface of the solar cell in order to enable the solar cells 10 to discharge electricity evenly. In addition, further contact fingers can be formed, which only extend within a solar cell 10 and collect the current (not illustrated in the figure).

The enlarged view shows how the cell connectors 15a are routed between two adjacent solar cells 10 from an upper side to a lower side. It is understood that the terminal connectors 110b according to exemplary embodiments can consist of wire bundles that are braided in the manner shown schematically in FIG. 2 .

2 also shows a cross-sectional view on the right, the section plane running along one of the cell connectors 15a, so that the solar cells 10 are each arranged between two cell connectors 15a. As stated, the cell connectors 15a run from an upper side of a first solar cell 10 to an underside of the following solar cell 10 in order to achieve a serial connection of the solar cells 10 in this way. Along the series connection, the last (or first) cell connector 15a makes contact with the cross connector 110b, which in turn makes contact with a number of solar cell rows 10a, 10b, . . . (see FIG. 1A).

3 shows a further exemplary embodiment in which both the cell connectors 110a and the cross-connectors 110b are designed as multi-wire connection connectors according to exemplary embodiments. Specifically, this figure shows two solar cells len io within a row of solar cells, which are connected serially with braided cell connectors noa. The cell connectors noa make contact with the cross-connector nob, both connectors being braided in this exemplary embodiment (see also the enlarged illustration in the lower section). As in other exemplary embodiments, the cell connectors 110a make direct contact with the solar cells 10 or the contact fingers on the solar cells in order to dissipate the current.

A cross-sectional view is again shown on the right-hand side of FIG. 3 , the cross-section running along a vertical direction and along an exemplary cell connector 110a. As in FIG. 2, the solar cells 10 are connected in series, i.e. each solar cell 10 is arranged between two adjacent cell connectors 110a.

Fig. 4 shows another embodiment, in which the cross-connector 15b are conventional and the cell connectors 110a are designed as a braided bundle according to Ausfüh approximately examples. The cross connector 15b is formed, for example, as a bus bar (for example, monolithically made of a metal). A cross-sectional view is also shown on the right, where, starting from the conventional cross-connector 15b, the solar cells 10 are serially connected to one another by means of the cell connectors 110a.

All other features or interconnections are identical to those shown in FIGS. 2 and 3, so that a repeated description is not necessary.

5 shows another embodiment in which the cell connectors are formed as a twisted bundle 120 while the cross-connector is formed as a braided ribbon 110b. In addition, at the bottom of FIG. 5 is an enlarged view of an exemplary twisted bundle 120 having a plurality of wires twisted into each other along a length. As already explained, however, twisting or twisting is not absolutely necessary.

In this exemplary embodiment, too, the solar cells 10 are in turn connected to one another in series by the cell connectors 120a being connected from a top side to a first Solar cell 10 are led to a bottom of the second solar cell 10 and so on. This can be seen again in the cross-sectional view on the right in FIG.

All other features and interconnections are identical to the previously described embodiments, so that a repeated description is not necessary. 6 shows an exemplary embodiment for the connection connectors within a photovoltaic module 20, in which the cross-connector 15b is again designed conventionally, while the cell connectors 120a are designed as a twisted bundle.

All other features or interconnections are designed as in the previous exemplary embodiments, so that a repeated description is not necessary.

FIG. 7 shows an exemplary embodiment for the connection connectors within a photovoltaic module 20, in which the cell connectors 15a are designed conventionally, while the cross-connector 120b is designed as a twisted bundle 120. FIG. The twisted bundle 120 of the cross-connector 120b comprises a plurality of wires twisted about one another along its length (see, e.g., the illustration of Figure 5 below).

All other features and interconnections are designed in the same way as in the previous exemplary embodiments, so that a repeated description is not required. 8 shows an exemplary embodiment for the connection connectors within a photovoltaic module 20, in which the cell connectors 110a are designed as braided ribbons, while the cross-connector 120b is designed as a twisted bundle 120. FIG.

All other features or interconnections are designed as in the previous exemplary embodiments, so that a repeated description is not necessary. 9 shows an exemplary embodiment for the connection connectors within a photovoltaic module 20, in which the cell connectors 120a and the cross-connector 120b are each designed as a twisted bundle 120. FIG.

All other features or interconnections are designed as in the previous exemplary embodiments, so that a repeated description is not necessary.

According to further exemplary embodiments, contact is only made from one side (e.g. from the rear) of the solar cells. The bundle 100 of wires (e.g. the cell connectors) then does not need to be routed from an upper side to an underside or vice versa. This is the case, for example, for back-contact solar cells or for so-called p-n-p arrangements, where p-type and n-type solar cells are arranged alternately.

10 shows an exemplary embodiment of a possible contacting of an electrical component 60, which is formed, for example, inside the connection box 40 or elsewhere in the photovoltaic module 20. FIG. The electrical component is, for example, a bypass element 60 (e.g. a diode). The current can be routed to the exemplary bypass element 60, for example, by means of one or more conventional busbars 15c. According to exemplary embodiments, a multi-wire connection connector can be formed as a component connector 110c between the busbar 15c and the bypass element 60 in each case.

The multi-wire connection connector can in particular include a braided bundle 110 or a twisted bundle 120 . In order to be able to better absorb thermal stresses, the electrical component 60 can be offset laterally, so that the current flow changes its direction (see second and fourth illustration from the left). The electrical component 60 can also be in line with the busbars 15 so that the current flow does not have to change its direction (see first and third illustrations from the left). In FIG. 10, the two illustrations on the right and the two illustrations on the left show views from opposite sides, ie the connection connector 110c can be above or below the busbar 15c be arranged (eg seen from a light incidence side).

The overlap between the terminal connectors 100 is advantageously chosen to be sufficiently large so that on the one hand the contact resistance is minimized and on the other hand the risk of detachment is minimized (i.e. even if some wires should detach, reliability is not compromised).

FIG. 11 schematically shows a flowchart for a method for electrically contacting solar cells 10 of a photovoltaic module 20. The method includes:

- providing Sno a bundle 100 of wires, the wires in the bundle being braided or twisted or untwisted; and

- Forming S120 of at least one of the following electrical connections using the bundle 100 of wires provided: a cell connector 100a through direct contact with at least one solar cell 10, a cross-connector 100b through direct contact with a cell connector 100a, a component connector 100c through a contact to an electrical component 60 of the photovoltaic module 20.

It goes without saying that, according to further exemplary embodiments, at least some of the bundles 100 need not be twisted or braided, or not completely, but that the individual wires within the bundle 100 are also held together in some other way. For example, the wires can be glued or soldered to one another at various points, or they can also be connected to one another in a form-fitting or force-fitting manner by holding means. Braiding or weaving, however, represents a special way of forming a durable and reliable conductor. The wires of the bundle 100 can also have a coating of a soft solder and/or a conductive plastic. This offers the advantage that by locally heating the bundle 100, the wires can be electrically connected to one another or to a conventional connector 15b, 15c. Exemplary embodiments overcome the problems of conventional connection connectors, for example through the use of braided wires in a solar module 20, whereby they can be used as busbars, cross-connectors of cell strings or connecting elements for example bypass diode 60 (PPT). Braided wires offer the further advantage that they absorb (elongation) stresses better and thereby reduce the risk of breakage at the edges of the solar cells 10 .

Other advantageous aspects relate to the increased flexibility and elasticity compared to conventional connectors. The connection connectors according to the exemplary embodiments have a lesser mechanical impact on the edges of the solar cells 10 or on the connections of diodes or other electrical components. The previously used monolithic connectors made of metal exhibit considerable thermal expansion, which leads to stresses during operation. For example, large forces act on the solar cells 10 when they are guided from one side to the opposite side. In addition, these stresses or forces can cause fractures or cracks that can result in significant damage.

According to exemplary embodiments, the terminal connectors comprise a multiplicity of wires (e.g. more than 5 or more than 10 or even 100 or more) which are untwisted, twisted or braided and therefore offer sufficient room for thermal expansion. Even if one or a few of these wires should break, the remaining wires can still carry the current. For this purpose, it can be particularly advantageous if the wires make electrical contact at several points along the current flow, so that any break points can be bridged.

However, the wires can also be provided with an insulating coating, at least in sections (eg to avoid leakage currents). However, the coating can also be conductive. The entire bundle (or the structure) or individual partial wires can have a copper core with a soft solder coating (eg containing lead or lead-free). Likewise, wires or parts thereof can have a copper core with a conductive plastic coating (polymers, epoxies, acrylates, silicon cone) have. In this way, the soldered or glued connection between different connectors (cell connector 100a, cross connector 100b, component connector io oc) can be achieved simply by local heating above the melting temperature of the solder or the plastic. According to exemplary embodiments, the component connector is thus replaced by a

Wire bundle contacted. The component connector can be used to connect an exemplary bypass diode (e.g. in the junction box). This type of contact offers the advantage that it can ensure reliable operation of the exemplary bypass diode, since mechanical stresses can be safely absorbed by the wire bundle or these do not arise in the first place.

If, for example, thermally-caused expansions of the cross-connector occur, these expansions can be absorbed or compensated for by the wire bundle without damaging the contacting of the component. In addition, since the cross-connector is designed as a busbar, a high current can still be derived from the solar cells with a low resistance.

Since a current only flows through the bypass diode when it is switched off or when voltage peaks occur (e.g. when it is darkened), a high current does not normally have to flow there. A wire mesh can therefore advantageously be used there in order to make reliable mechanical cushioning possible. The wire mesh therefore has no negative impact on the electrical resistance in normal operation, since the (high) current is dissipated through the busbar of the cross connector with a low resistance - without the current flowing through the wire bundle of the component connector.

The features of the invention disclosed in the description, the claims and the figures can be essential for realizing the invention, both individually and in any combination. REFERENCE LIST

IO solar cell(s)

15 conventional port connector

20 photovoltaic module

40 junction box

50 connection cables

6o electrical/electronic component (e.g. bypass element)

100 bundles of wires

110 braided bundle

120 twisted bundle

140 untwisted bundle

110a, 120a, 140a cell connectors according to exemplary embodiments 110b, 120b, 140b cross-connectors according to exemplary embodiments 110c, 120c, 140c component connectors according to exemplary embodiments

Claims

CLAIMS l. Photovoltaic module comprising: a plurality of solar cells; and at least one multi-wire connection connector for deriving an electrical current from a plurality of solar cells within a photovoltaic module, the connection connector comprises: a bundle of wires, the wires:

- a braided bundle or

- form a twisted bundle, or - form an untwisted bundle and the bundle is arranged to provide the following electrical connection:

- A component connector having a contact to an electrical component of the photovoltaic module, wherein a cross-connector for deriving the current from the solar cells as one

Busbar between a cell connector, which has a contact to at least one solar cell, and the component connector is ausgebil det.

2. Photovoltaic module according to claim 1, wherein the wires in the bundle are held together by braiding or weaving or gluing or welding or is ensured by holding means.

3. The photovoltaic module according to claim 2, wherein the bundle of wires has a braided flat shape in a cross section perpendicular to a direction of current band forms.

4. Photovoltaic module according to one of the preceding claims, wherein the

Wires within the bundle are at least partially electrically isolated from one another or electrically connected to one another.

5. Photovoltaic module according to one of the preceding claims, wherein at least some of the wires of the bundle have a coating of a soft solder and/or a conductive plastic.

6. Photovoltaic module according to one of the preceding claims, wherein the wires are made of copper or have a copper core.

7. Photovoltaic module according to one of the preceding claims, which has at least one bypass element for dissipating an electrical overvoltage as an electrical component, wherein the at least one bypass element is electrically contacted by the component connector with the bundle of wires.

8. Method for electrically contacting solar cells of a photovoltaic module, the method includes:

providing a bundle of wires, the wires in the bundle being braided or twisted or untwisted; and

Forming at least one of the following electrical connections using the bundle of wires provided:

- a cell connector through a contact to at least one solar cell,

- a component connector through a contact to an electrical component of the photovoltaic module, wherein a cross connector for deriving the current from the solar cells is formed as a current bus bar between the cell connector and the component connector.

9. The method according to claim 8, wherein at least part of the wires of the bundle has a coating of a soft solder and/or a conductive plastic and the method further comprises:

Locally heating the bundle of wires to electrically connect the wires to each other or to a current collection device.