WO2013091871A1 - Photovoltaic system and interconnector for connecting a photovoltaic module - Google Patents

Abstract

A photovoltaic system is described and shown having a plurality of photovoltaic modules (1), each of which includes two connecting cables (2), an inverter (3) and a twin-wire interconnector (4) or two single-wire interconnectors (41, 42), wherein each of the wires (7) of the twin-wire interconnectors (4) or the wires (7) of the two single-wire interconnectors (41, 42) are encased in a wire insulation (8), and wherein the photovoltaic modules (1) are linked to the inverter (3) via the interconnector (4) or the interconnectors (41, 42). The photovoltaic system according to the invention ensures minimal risk of personal injury by electrical shock in the event of damage in that wire insulations (8) of the two wires (7) of the twin-wire interconnector (4) are jointly encompassed by a pre-tensioned spring element (9), or each of the wire insulations (8) of the wires (7) of the two single-wire interconnectors (41, 42) are encompassed by a pre-tensioned spring element (9), and in that the spring elements (9) consist of an electrically conductive material and the wire insulations (8) consist of a material that melts upon heating beyond a certain temperature, such that upon melting of the wire insulation (8) each spring element (9) makes contact with the wires (7).

Description

 Photovoltaic system and connection line

 for connecting a photovoltaic module

The invention relates to a photovoltaic system with several photovoltaic modules, each having two connecting lines, with a converter and with a two-wire connecting line or two single-core connecting lines, wherein the two wires of the two-wire connecting line or the wires of the two single-core connecting lines each surrounded by a core insulation and wherein the photovoltaic modules are connected via the connecting line or the connecting lines to the inverter. In addition, the invention also relates to a connecting line for the electrical connection of a photovoltaic module, with at least one core and with a wire insulation surrounding the core.

To generate electricity from sunlight photovoltaic modules are increasingly used to convert the sunlight into electrical energy. Such photovoltaic modules, which are often referred to as solar panels, consist of a plurality of individual solar cells, which are arranged side by side lying between a common front cover layer and a common back cover layer and interconnected. To achieve higher voltages, usually several photovoltaic modules are connected in series. For this purpose, each Photovolta- ikmodul associated with a junction box, which is fixed on the side facing away from the sun side of the photovoltaic module. The connecting cables coming from the solar cells of the photovoltaic module, which are generally flat cables, are electrically conductively connected in the junction box to the input-side connecting elements, which are electrically connected within the junction box to output-side connecting elements for connecting external lines. Via the external lines, which are connected to the output-side connection elements, several photovoltaic modules can be connected to each other, so that a series connection is created, which is usually referred to in photovoltaic systems as a string (or strand).

CONFIRMATION COPY While in smaller photovoltaic systems one or more (few) strings are connected directly to a converter, with somewhat larger photovoltaic systems, at least one string connection box is used, to whose input-side connection elements several string lines or the wires of the individual string lines are connected. The string connection box is then connected to the output side via a two-core connection cable or via two single, single-core connection cables.

Inverters are usually inverters (often referred to as inverters) used to convert the DC voltage supplied by the photovoltaic modules in an AC voltage, which can then be fed into the power grid. Is the photovoltaic system a grid-independent photovoltaic system, i. H. a so-called isolated solution, in which the photovoltaic system is not connected to the general power supply network, then a charge controller is used as the inverter. The charge controller is located between the photovoltaic modules and the battery or the battery and ensures that the battery is neither charged with too much power (overcharge protection) nor too heavily discharged, which can also adversely affect the battery life. In the context of the present invention, both inverter and charge controller should be encompassed by the term converter.

Photovoltaic modules have the property that they provide electrical energy in the form of a DC voltage when light is incident on the solar cells. Even with weak light sources, such as street lighting or moonlight, a voltage may already be applied to the photovoltaic module, which is dangerous when touched by persons, since for people already a DC voltage of 120 V represents a danger to life and limb. Depending on the size and interconnection of the photovoltaic modules with each other, the DC voltage generated at the generator terminals in the range of 1000 V or more. As long as light reaches the photovoltaic modules, there is therefore the risk of an electric shock for persons in contact with the DC voltage side.

Particularly in the case of a fire in a building on which or in the vicinity of which a photovoltaic system is installed, the photovoltaic system taikmodulen generated DC voltage pose a danger to persons especially for the emergency services, since the extinguishing water can come into contact with live cables and components. During operation, however, DC voltage-carrying lines must not be interrupted without further ado, since an arc resulting from the switching operation represents an additional risk of fire and injury. A demanded for example in VDE 0100-712 DC-disconnection point in front of the inverter does not eliminate the risk of voltage over the fire water, since even with the open switch to the photovoltaic system and the line system up to the activation point applied to the DC voltage generated by the photovoltaic modules.

To remedy this situation, tarpaulins are known from practice, which are hung in the event of fire on the individual photovoltaic modules. However, since the individual photovoltaic modules are usually mounted on the roof of a building, this measure is relatively time-consuming, so that it has not proved suitable in the application, especially as additional Einsätzkräfte be bound by the application of the cover tarpaulins.

From DE 10 2007 032 605 AI a photovoltaic system is known, in which the current flow through the individual photovoltaic modules is controllable. For this purpose, the individual photovoltaic modules preferably have a control unit with a receiver, an amplifier and a relay, so that an internal short circuit in the photovoltaic module can be generated by actuation of the switch. Although this allows the individual photovoltaic modules to be de-energized, the prerequisite is that the remote controllable switch is working properly and is properly activated.

The present invention is therefore based on the object to provide a photovoltaic system available, which is reliably transferred in the event of a fire in a safe operating condition. In addition, the invention has the object, a connecting line for the connection of a photovoltaic module in a photovoltaic system in such a way that this in the simplest possible and yet reliable way the Überf h- tion of the photovoltaic system in the safe operating state supported or guaranteed.

This object is achieved in the photovoltaic system described in the introduction with the features of claim 1, characterized in that the core insulation of the two wires of the two-wire connection line are jointly covered by a prestressed spring element or the wire insulation of the cores of the two single-core connecting lines each of a prestressed spring element. The spring elements consist of an electrically conductive material, in particular of metal, and the wire insulation of a material that melts when heated above a certain temperature, so that upon reaching the melting temperature, the wires are covered by the respective spring element.

If the photovoltaic system has a two-core connecting line, then the core insulation of the two cores is jointly covered by a spring element, wherein the spring element is designed or dimensioned so that it touches the cores in the absence of wire insulation, so that the two cores short-circuited via the spring element are. In the normal state, when the wires are surrounded by the wire insulation, then the spring element, which surrounds the wire insulation, biased against its spring force. If there is an inadmissible heating of the connecting line, for example due to a fire occurring in the region of the connecting line, this leads to the fact that the core insulation melts, so that the spring element relaxes so much that it touches the two wires of the two-wire connecting line and thus the shorts both wires in this area. As a result, the applied voltage is reduced to zero, so that a risk to persons due to a high voltage is excluded.

If the photovoltaic system does not have a two-core connecting lead but two single-core connecting leads, the core insulation of the leads of the two single-ended connecting leads is in each case encompassed by a prestressed spring element. If, in this case, the insulation of the wire melts due to a fire, for example, this also leads to Always pull the spring elements together until they touch the wires.

In order to exclude a risk to persons due to an impending high voltage even when using two single-core connection lines, according to a first variant of the photovoltaic system according to the invention, a short-circuit is also intentionally generated between the two individual wires. For this purpose, the spring elements of the two connecting lines are electrically conductively connected to each other, wherein the electrically conductive connection of the spring elements is preferably carried on at least one end of the two spring elements. This variant is used in particular in smaller or medium-sized photovoltaic systems, in which the current flowing through the short-circuited spring elements is usually not more than a few 10 A.

In the case of larger photovoltaic systems, on the other hand, very large currents of several 100 A can flow via the connecting lines. Although in principle a desired short circuit of the two single-core connecting lines is possible here, too, so that the spring elements can carry such high short-circuit currents, they would, however, have correspondingly large cross-sections, which would considerably increase the costs of the connecting lines. Therefore, according to a second variant of the photovoltaic system according to the invention, it is provided that in each case one core of one connecting line and the prestressed spring element surrounding the core of the other connecting line are connected to a voltage monitoring device. In this case, the voltage monitoring device supplies a disconnection signal to a switching element when the voltage measured by the voltage monitoring device between the core of one connecting line and the spring element of the other connecting line exceeds a limit value.

In this variant, the spring elements of the two connecting lines are thus not electrically conductively connected to each other, so that no short circuit between the spring elements and the two connecting lines is generated. The spring elements are thus not used to transmit a short circuit, but as signal lines, so that they are also at large photovoltaic systems do not need to have a particularly large cross-section. In the normal state, the wires and the spring elements are insulated from each other by wire insulation. The voltage monitoring device then measures the voltage between the core of one connecting line and the spring element of the other connecting line. However, if the wire insulation has melted, the spring element contacts the associated wire, so that the voltage monitoring device measures the voltage between the two wires. This is then used as an enable signal for a large photovoltaic system anyway most existing switching element, which switches on the connection line freely.

Thus, the spring element or the spring elements reliably contact the wires in case of damage, it is preferably provided that the spring element has at least one turn, the two core insulation - in a two-wire connection line - or the core insulation - in two single-core connecting lines - by at least 180 ° includes. As a result, the spring element surrounds the core insulation or the wire insulation in a clip-like manner, so that the spring element, which contracts when the core insulation melts, securely surrounds the wires or core and thus produces a good electrical contact with the wires or core.

In particular, when a two-core connection line is used, the use of a spring element with only one turn is basically sufficient. So that in such a configuration, regardless of which area of the photovoltaic system the fire breaks out first, a fire quickly detected and then a short circuit between the two wires is realized, several such, each having a turn spring elements must be arranged along the connecting line. According to an advantageous embodiment of the invention it is therefore provided that the spring element has not only one turn, but a plurality of turns and is arranged spirally around the two wire insulation or the wire insulation in a single-core connecting line. The spring element preferably extends substantially over the entire length of the connecting line, so that a fire is reliably detected, regardless of the area of the photovoltaic system in which a fire is initially detected. breaks. As a result, a complete protection of the entire photovoltaic system is achieved without requiring an active control measure by a person, such as the fire department, is required.

The use of a multi-turns and the wire insulation spirally surrounding spring element also has the advantage that the spring element also increases the mechanical strength of the connecting line. Thus, the spring element - as a side effect to the actual short-circuit function - also provides protection against damage to the connecting line, for example, by the bite of an animal.

To protect the connecting line, this usually has in addition to the wires and the wire insulation also a line insulation, which surrounds the spring element. In principle, the cable insulation can consist of the same or a similar material as the core insulation. However, it is also conceivable that the line insulation consists of a material that is more temperature-resistant than the material of the core insulation. When a fire occurs, it then first melts the core insulation, causing the short-circuit function of the spring element is triggered while the line insulation is not damaged. Of course, the material of the cable insulation must be selected so that it does not shield the wire insulation thermally, otherwise the desired thermal detection of a fire would be prevented by the melting of the wire insulation.

The above object is achieved in a connecting line for the electrical connection of a photovoltaic module with the features of claim 8, characterized in that the core insulation is comprised of a prestressed spring element, and that the spring element of an electrically conductive material and the wire insulation is made of a material that melts when heated from a certain temperature, so that upon reaching the melting temperature, the wire is covered by the spring element.

As has been explained above in connection with the photovoltaic system according to the invention, when the connecting line is a two-wire connecting line, the two wire isolations are comprises two-wire connecting line together of a prestressed spring element. If the connection line is a two-core connection line, then - as stated above - both cores are surrounded by a core insulation. In this case, the wire insulation of the two wires can be separated from each other, but it is also possible that the two wire insulations merge into each other, so that the two wires of the connecting line are mechanically connected to each other via the wire insulation. Of course, then, if the two wire insulation are connected together, it is thus only functionally two core insulation, it must be ensured that the two wires are separated from each other by the wire insulation and thus insulated.

Even with the connecting line according to the invention, the spring element preferably has a plurality of turns and is arranged spirally around the wire insulation or the two wire insulation. In addition, it is also preferably provided that the spring element is surrounded by a line insulation, so that the connecting line has at least one core, at least one core insulation, a spring element and a line insulation.

In particular, there are a variety of ways to design and further develop the photovoltaic system according to the invention or the connecting line according to the invention. Reference is made to both the patent claims 1 and 8 subordinate claims as well as the following description of preferred exemplary embodiments in conjunction with the drawings. In the drawing shows:

1 is a schematic representation of a photovoltaic system according to the invention,

2 shows a first embodiment of a two-wire connecting line according to the invention, normally and with partially melted wire insulation,

3 is a detailed view of the connecting line of FIG. 2, Fig. 4 shows a second exemplary embodiment of a two-wire connecting line according to the invention, in the normal case and with partially melted wire insulation, and

Fig. 5 shows an embodiment of a single-core according to the invention

 Connecting line, normally and with partially melted wire insulation.

In Fig. 1, a photovoltaic system according to the invention is schematically shown, which has a plurality of arranged on a roof photovoltaic modules 1, each with two connecting lines 2 and designed as an inverter 3 inverter. In the exemplary embodiment illustrated schematically, the photovoltaic modules 1 are connected to the inverter 3 via two single-core connecting lines 41, 42. The inverter 3 has the task of converting the supplied from the photovoltaic modules 1 and transmitted via the connecting lines 41, 42 DC voltage into an AC voltage, which can then be fed into an AC voltage network 5. In order to transmit a higher voltage via the connecting lines 41, 42, several photovoltaic modules 1 are connected in series to a string 6.

Instead of using two single-core connecting lines 41, 42, the photovoltaic modules 1 can also be connected to the inverter 3 via a two-wire connecting line 4. A part of such a two-wire connecting line 4 is shown in FIG. The connecting line 4 has two wires 7, which are each surrounded by a core insulation 8. Moreover, in the case of the connecting line 4 according to the invention, the two core insulations 8 are jointly covered by a prestressed spring element 9, wherein the spring element 9 has a plurality of turns 10 and is arranged spirally around the two core insulations 8. The spring element 9 extends substantially over the entire length of the connecting line 4. Finally, the connecting line 4, a line insulation 1 1, which surrounds the spring element 9, wherein in the illustration of FIG. 2, a part of the line insulation 1 1 has been omitted is, so that the underlying wires 7 with the wire insulation 8 and the spring element 9 are visible. The spring element 9 provided according to the invention consists of an electrically conductive material, in particular of metal, and is designed or dimensioned such that it touches the two wires 7 in the absence of wire insulation 8. The core insulation 8 consist of a material that melts when heated above a certain temperature. The temperature or the material is chosen so that the material melts in the event of a fire. Since the spring element 9 in the normal state of the connecting line 4 (FIG. 2a) surrounds the wire insulation 8 of the two wires 7, the spring element 9 is then biased against its spring force. This then leads to (Fig. 2b) that the two wires 7 are touched with molten wire insulation 8 in the region of the damaged or molten wire insulation 8 of the spring element 9 and thus short-circuited. A voltage applied to the connecting line 4 voltage is thus automatically reduced to zero in the event of a fire, so that there is no danger for people in contact with the photovoltaic system or the connecting line 4 to get an electric shock.

Fig. 3 shows a part of the connecting line 4 according to FIG. 2, wherein here for simplicity, the line insulation 1 1 is completely omitted. In the case of short circuit shown in FIG. 3, the two wires 7 of the two-wire connection line 4 are contacted and thus short-circuited in the area in which the core insulation 8 has melted due to the heat which has occurred in the event of a fire by the spring element 9 spirally surrounding the two wires 7 ,

Fig. 4 shows a second embodiment of a two-wire connecting line 4 according to the invention, in which again the line insulation 1 1 is only partially shown. In contrast to FIGS. 2 and 3, in this case the spring element 9 has only one turn 10, which in the normal case (FIG. 4 a) surrounds the two core insulations 8 by a little more than 180 °. Here, too, heating of the wire insulation 8 causes the wire insulation 8 to melt and then the spring element 9 pulls together so that it contacts the two wires 7 and thus short-circuits it (FIG. 4b).

The embodiment shown in FIGS. 2 and 3 with a plurality of windings having spring element 9, which extends substantially over the extends the entire length of the connecting line 4, has the advantage that this quickly detects a fire occurring and then a short circuit is brought about, regardless of where the connection line 4, the fire occurs. So that this can also be achieved in the embodiment of the spring element 9 shown in FIG. 4, several such spring elements 9 must be attached at different points along the connecting line 4.

2 to 4, a two-wire connecting line 4 is shown, in which the two wires 7 are each surrounded by its own wire insulation 8. Such a two-wire connection line 4 can be produced simply by winding the spring element 9 around the lines arranged next to one another and each having a wire insulation 8 and then being surrounded by the line insulation 11. In an alternative embodiment of a two-wire connecting line 4, the two wires 7 may also be surrounded by a common wire insulation 8, which is then surrounded by the spring element 9 spirally, d. H. the wire insulation 8 of the two wires 7 merge into each other.

Fig. 5 shows an embodiment of a single-core connecting line 41 according to the invention, in which the wire 7 is surrounded by a wire insulation 8 and this in turn by a prestressed spring element 9 spirally. As in the exemplary embodiment of the two-wire connecting line 4 according to FIG. 2, the spring element 9 also has a plurality of windings 10 and extends substantially over the entire length of the connecting line 41. Here, too, the core insulation 8 melts when the temperature surrounding the connecting line 41, For example, due to a fire, the melting temperature has reached, so that then relaxes the prestressed spring element 9 so far that it contacts the wire 7 in the area in which the wire insulation 8 is melted.

In order to generate a short circuit between the two wires 7 of the connecting lines 41, 42 in the event of a fire when using two such single-core connecting lines 41, 42, the spring element 9 of a connecting line 41 to the spring element 9 of the second connecting line 42 is electrically connected, which achieved, for example can be that both spring elements 9 are connected to ground or ground potential. Alternatively, in each case one core 7 of the two connecting lines 41, 42 and the biased spring element 9 surrounding the core 7 are connected to a voltage monitoring device (not shown here). The voltage monitoring device then supplies a disconnection signal to a switching element of the photovoltaic system when the voltage measured by the voltage monitoring device between the wire 7 and the spring element 9 falls below a limit value. By the switching element, the connection line is then released.

In Fig. 1 it is shown that the photovoltaic system in addition to the photovoltaic modules 1 and the inverter 3 still has a string connection box 12 to which a plurality of strings 6 - of which in Fig. 1 only one is shown - can be connected. The string connection box 12 serves to connect the connecting lines of the string to the connecting lines 41, 42 which are laid between the string connection box 12 and the converter 3. The connecting lines of the string can also be designed as self-shorting connecting lines, i. H. also have a spring element surrounding the wire insulation.

In addition, the junction boxes 13 are shown in Fig. 1, by means of which the individual photovoltaic modules 1 are connected to the string 6 and the connecting lines 41, 42. In addition, it is indicated that a suitable short-circuit device 14 can additionally be arranged both in the string connection box 12 and in the individual connection boxes 13, by which the voltage applied to the connecting lines 2 of the photovoltaic modules 1 or to the string connection box 12 is present when they are activated Zero can be reduced.

Claims

claims:

1. Photovoltaic system with a plurality of photovoltaic modules (1), each having two connecting lines (2), with an inverter (3) and with a two-wire connecting line (4) or two single-core connecting lines (41, 42), wherein the two wires (7) The two-wire connecting line (4) or the wires (7) of the two single-core connecting lines (41, 42) are each surrounded by a core insulation (8) and wherein the photovoltaic modules (1) via the connecting line (4) or the connecting lines (41, 42) are connected to the inverter (3),

characterized,

that the wire insulation (8) of the two wires (7) of the two-wire connecting line (4) together by a prestressed spring element (9) or the wire insulation (8) of the wires (7) of the two single-core connecting lines (41, 42) each of a prestressed spring element (9) are included, and

that the spring elements (9) consist of an electrically conductive material and the wire insulation (8) of a material that melts when heated above a certain temperature, so that when molten wire insulation (8) the respective spring element (9) the wires (7) contacted.

2. Photovoltaic system according to claim 1, characterized in that the spring element (9) has at least one turn (10) which comprises the two wire insulation (8) or the wire insulation (8) by at least 180 °.

3. Photovoltaic system according to claim 2, characterized in that the spring element (9) has a plurality of windings (10) and is arranged spirally around the two wire insulation (8) or the wire insulation (8).

4. Photovoltaic system according to one of claims 1 to 3, characterized in that the spring element (9) by a line insulation (1 1) is surrounded, wherein the line insulation (1) is preferably made of a material which is more temperature resistant than the material of the core insulation ( 8).

5. Photovoltaic system according to one of claims 1 to 4, with two single-core connecting lines (41, 42), characterized in that the prestressed spring elements (9) of the two connecting lines (41, 42) are electrically conductively connected to each other.

6. Photovoltaic system according to one of claims 1 to 5, characterized in that the spring element (9) or the spring elements (9) is connected to ground or earth potential or are.

7. Photovoltaic system according to one of claims 1 to 4, with two single-core connecting lines (41, 42), characterized in that at least one switching element is provided which switches a connecting line (41, 42) in case of failure, and that in each case one core ( 7) of the one connecting lines (41, 42) and the biased spring element (9) surrounding the core (7) of the other connecting line (42, 41) are connected to a voltage monitoring device, wherein the voltage monitoring device activates a disconnection signal the switching element delivers when the voltage measured by the voltage monitoring device between the wire (7) of one connecting line and the spring element (9) of the other connecting line (41, 42) exceeds a limit value.

8. connection line for the electrical connection of a photovoltaic module (1), with at least one core (7) and with a wire insulation (7) surrounding the core insulation (8),

characterized,

in that the core insulation (8) is covered by a prestressed spring element (9), and

in that the spring element (9) consists of an electrically conductive material and the wire insulation (8) consists of a material which melts when heated above a certain temperature, so that when the wire insulation (8) is molten, the spring element (9) contacts the wire (7) ,

9. connecting line according to claim 8, with two wires (7), each surrounded by a wire insulation (8), characterized in that the the wire insulation (8) of the two-wire connecting line (4) are jointly covered by a prestressed spring element (9).

10. Connecting line according to claim 8 or 9, characterized in that the spring element (9) has at least one turn (10) which comprises the core insulation (8) or the two wire insulation (8) together by at least 180 °.

1 1. Connecting line according to claim 8 or 9, characterized in that the spring element (9) has a plurality of windings (10) and is arranged spirally around the wire insulation (8) or the two wire insulation (8).

12. Connecting line according to one of claims 8 to 1 1, characterized in that the spring element (9) by a line insulation (1 1) is surrounded, wherein the line insulation (1 1) preferably consists of a material which is more temperature resistant than the material of Core insulation (8) is.

13. Connecting line according to one of claims 8 to 12 for use in a photovoltaic system according to one of claims 1 to 7.