FR2956533A1 - Electrical installation for e.g. public usage building, has units switching direct current generating units between configuration and another configuration ensuring activation of direct current generating unit short-circuiting units - Google Patents

Abstract

The installation (10) has direct current generating units (12) comprising a photovoltaic module (16) for supplying power to a load circuit (14), and short-circuiting units (CC1-CC3) for short-circuiting the direct current generating units. Switching units (26) switch the direct current generating units between a configuration supplying the power to the load circuit and another configuration ensuring isolation of the generating units with respect to the load circuit and activation of the short-circuiting units of the direct current generating units. An independent claim is also included for a device for electrical connection of a direct current generating unit and a load circuit.

Description

The present invention relates to the field of electrical installations comprising direct current generating means comprising at least one photovoltaic module. In what follows, a photovoltaic module is an assembly comprising at least one photovoltaic cell producing, when exposed to light, generally in the light of the sun, a DC voltage. A photovoltaic module generally comprises a plurality of photovoltaic cells electrically connected to each other so as to form a dipole at the terminals of which the voltage can reach several tens of volts, for example 30 to 120 volts, depending on the type of module.

The photovoltaic modules can also be electrically connected to each other in series or in parallel. Already known in the state of the art DC generating means comprising photovoltaic modules for supplying a charging circuit such as for example an electric circuit equipping a public or private building. In this case, the building, usually the roof of this building, is equipped with photovoltaic modules forming the direct current generating means. Since it is usually desired to have alternating current in the load circuit fitted to the building, the photovoltaic modules are generally connected to the charging circuit via an inverter (or several inverters). The inverter transforms the direct current generated by the photovoltaic modules into alternating current having characteristics of frequency, intensity and voltage required by the equipment or electrical networks connected to the inverter.

In the case of a building equipped with photovoltaic modules, it is desired to be able to isolate the load circuit of the building from all the means generating current, in particular to allow, in complete safety, a maintenance operation or management of a building. sinister (flood, fire, etc.) suffered by the building.

However, when the current-generating means comprise photovoltaic modules, the isolation of these generating means with respect to the load circuit of the building does not prevent the existence of a voltage at the terminals of the photovoltaic modules. Indeed, they remain exposed to the outside light of the building. The voltage remaining at the terminals of the photovoltaic modules therefore constitutes a danger for the intervention teams. The object of the invention is to isolate current generating means comprising photovoltaic modules with respect to a charging circuit 2956533 -2- usually connected to these modules, for example an electrical circuit fitted to a building, this avoiding that there remains at the terminals of photovoltaic modules a significant voltage, likely to interfere with a response team. To this end, the subject of the invention is an electrical installation comprising direct current generating means comprising at least one photovoltaic module intended to supply a charging circuit, characterized in that it comprises means for putting into effect circuit of the generating means, and means (26) for switching the generating means between a first configuration ensuring the supply of the charging circuit and a second configuration ensuring both the isolation of the generating means with respect to this circuit. charging and activating means for short-circuiting generating means. The invention is opposed to the principle usually adopted by those skilled in the art to avoid short-circuiting a power source. Indeed, the skilled person usually considers that the short circuit of a power source permanently destroys this source. Contrary to this prejudice, the invention has made it possible to establish that the short-circuiting of the photovoltaic modules does not deteriorate them, as they prove to be capable of dissipating the energy produced by placing them in short-circuit. circuit. Not being damaged by their short-circuiting, the photovoltaic modules are again operational after suppression of short circuits. Thus, in the event of a maintenance operation in a building provided with an electrical installation according to the invention or in the event of a disaster suffered by this building, the switching means of the invention make it possible to place the current generating means in the second configuration ensuring both the isolation of the generating means with respect to the charging circuit and the activation of the short-circuiting means of the generating means. The short-circuit voltage at the terminals of the photovoltaic modules, theoretically zero, is in practice negligible. There is therefore no danger for the possible intervention teams. When the maintenance operation is terminated or when the disaster is terminated, the switching means make it possible to replace the current generating means in the first configuration which supplies the charging circuit, since the photovoltaic modules not damaged and thus able to feed the charging circuit again. According to other optional features of the invention: the switching means of the generating means comprise relay means controlled by an electrical control circuit, the first configuration of the switching means being imposed by a powered state. of the control circuit and the second configuration of the switching means being imposed by a non-powered state of the control circuit; the relay means are of the electromechanical type, the control circuit forming a supply circuit for the two electromagnet means of the electromechanical relay means; The control circuit comprises means for opening this control circuit comprising means for manually or automatically stopping the power supply of the charging circuit; the opening means of the control circuit comprise means for manually controlling the emergency stop of the power supply of the charging circuit, for example of the push-button type; the opening means of the control circuit comprise means for manual control of the non-emergency stop of the power supply of the charging circuit, for example for maintenance purposes of the charging circuit; the opening means of the control circuit comprise means 20 forming a differential circuit-breaker; the installation comprises: at least two photovoltaic modules for supplying a charging circuit and an electrical connection device comprising means for electrically connecting these modules in series, the means for short-circuiting the generating means and the switching means of the generating means. The invention also relates to an electrical connection device intended to connect, on the one hand, direct current generating means 30 comprising at least two photovoltaic modules to, on the other hand, a charging circuit, this device comprising electrical connection means in series of two photovoltaic modules, characterized in that it comprises means for short-circuiting the generating means, and switching means of the generating means between a first configuration ensuring the supply of the circuit a second configuration ensuring both the isolation of the generating means with respect to this charging circuit and the activation of the means for short-circuiting the generating means. According to an optional feature of this connection device, the latter comprises a housing in which are housed: the electrical connection means in series of two photovoltaic modules, the means for short-circuiting the generating means, and switching means of the generating means.

The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the single figure showing a diagram of an electrical installation according to the invention. There is shown in the single figure an electrical installation according to the invention designated by the general reference 10. In this example, the installation 10 is intended to equip a building for private or public use. The installation 10 comprises means 12 DC generators for supplying a charging circuit 14. The DC generator means 12 comprise at least one photovoltaic module 16 of conventional type. The module 16 comprises an assembly 20 of photovoltaic cells, electrically interconnected, of a conventional type, for example crystalline silicon type, amorphous silicon, thin-film type AsGa, CdTe, CIS or organic material. Depending on the type, the module 16 may be flexible or rigid. A rigid module is usually called a "panel". In the example illustrated, the means forming direct current generators 12 comprise several photovoltaic modules 16 of which only three are shown in the figure. Each photovoltaic module 16 forms a dipole delivering at its terminals a direct current. Instead of one or each photovoltaic module 16, it is possible to provide a chain of photovoltaic modules 16 interconnected electrically in a manner known per se.

Photovoltaic modules 16 are intended to be exposed to external light. For this purpose, they are placed for example on the roof of the building. Referring to the figure, it can be seen that the installation 10 comprises at least one conventional inverter 18 connected, as input, to the photovoltaic modules 16 and, at the output, to an electric circuit 20 of alternating current forming part of the circuit 35. load 14, equipping the building. The electrical circuit 20 is for example a three-phase electrical network. The installation 10 also comprises at least one electrical connection device 22 comprising a housing 23 provided, for example as shown in the figure, with three dipole inputs ED1, ED2, ED3 and an SD dipole output. . Each photovoltaic module 16 (or chain of photovoltaic modules 16) 5 is electrically connected to a corresponding dipole input ED1, ED2, ED3. The dipole output SD is electrically connected to the inverter 18. The housing 23 contains means for series connection of the photovoltaic modules 16 and means for short-circuiting each photovoltaic module 16.

The series connection means of the modules 16 comprise a series connection circuit 24 electrically connected to the output SD of the housing 23. The short-circuiting means of the modules 16 comprise a corresponding circuit CC1, CC2, CC3 for each module 16. These circuits CC1, CC2, CC3 thus allow the short-circuiting of all the generating means 15 DC generator shown in FIG. The housing 23 also contains means 26 for switching the generating means 12 between: a first configuration ensuring the supply of the charging circuit 14, and a second configuration, as represented in the figure, ensuring both the isolation generating means 12 with respect to this charging circuit 14 and the activation of the means for short-circuiting the generator means 12. In the example illustrated, the switching means 26 comprise three electromechanical power relays R1, R2, R3. Each relay R1, R2, R3 has two open / closed changeover contacts K1, K2, K3.

Each contact K1, K2, K3 is electrically permanently connected to a photovoltaic module pole 16 via dipole inputs ED1, ED2, ED3. Each relay R1, R2, R3 comprises an electromagnet, which has shown a coil B1, B2, B3, for the displacement of the corresponding contacts K1, K2, K3 between a short-circuiting position of each photovoltaic module 16, as shown in the figure, and a series connection position of the photovoltaic modules 16. Thus, in their position shown in the figure, the contacts K1, K2, K3 are connected to the corresponding short-circuiting circuits CC1, CC2 , CC3 and, in their other position, the contacts K1, K2, K3 are connected to corresponding sections of the series connection circuit 24. The housing 23 also contains a circuit 28 for supplying the coils B1, B2, 2956533 - 6- B3 connected to an EC input of the housing 23 intended to be connected to a circuit 30, outside the housing 23, for controlling the relays R1, R2, R3. In the example shown, the coils B1, B2, B3 are powered by alternating current. The control circuit 30 thus comprises a first phase line 32 and a second phase or neutral line 34. These lines 32, 34 are connected to the control input EC of the housing. As a variant, the coils B1, B2, B3 of the relays could be powered by direct current. The control circuit 30 comprises means for opening this circuit 30 comprising elements for manually or automatically stopping the supply of the charging circuit 14. Indeed, the phase line 32 of the control circuit 30 comprises a conventional push-button switch 35 forming means for manual control of the emergency stop of the supply of the load circuit 14.

The push-button 35 is housed in an access box (not shown) adapted to allow exceptional access to this push-button. The push-button has a structure adapted to its emergency stop function. . For example, the pushbutton 35 remains locked in the open position of the control circuit 30 when it is actuated urgently.

Furthermore, the phase line 32 of the control circuit 30 comprises a conventional contactor 36 forming means for manually controlling the non-emergency stop of the supply of the load circuit 14, for example for maintenance purposes of the Installation 10. Finally, the phase line 32 of the control circuit 30 comprises conventional means 38 forming a differential circuit breaker ensuring automatic shutdown of the supply of the load circuit 14 in the event of an electrical fault. It will be noted that the push button contactor 35, the contactor 36 and the differential circuit breaker 38 are arranged in series on the phase line 32 of the control circuit 30.

It will also be noted that the opening means (push-button contactor 35, contactor 36 or differential circuit-breaker 38) of the control circuit 30 can be placed, on the one hand, in a waiting state in which the circuit of FIG. command 30 is closed and, on the other hand, in an open state of the control circuit 30, so that the transition from the open state to the waiting state can be achieved by a single action on a single member (pushbutton 35, contactor 36 or GFCI 38). This single action on a single unit reactivates the supply of the entire charging circuit 14, regardless of the number of electromechanical relays R1, R2, R3 used, provided that all the relays are connected to the same control circuit 30. In a variant, the electromechanical relays R1, R2, R3 may be replaced by static power relays.

The electrical system 10 according to the invention has many advantages. The first configuration of the switching means 26 is imposed by a powered state of the control circuit 30. This first configuration corresponds to the normal operation of the electrical installation 10. The second configuration of the switching means 26 is imposed by a non-powered state. of the control circuit 30. This second configuration is established for example, manually, when the emergency stop button 35 is actuated or automatically when the differential circuit breaker 38 detects a current fault. The second configuration can be established also in non-urgent cases, for example when it is desired to carry out a maintenance operation of the installation. It suffices to manually operate the switch 36. Finally, the second configuration can be established automatically when an accidental cut occurs in the control circuit 30. When the switching means 26 are in their second configuration, the coils B1 , B2, B3 relays are no longer powered so that the contacts 20 K1, K2, K3 are in their rest position shorting each photovoltaic module 16. The voltage at the terminals of each photovoltaic module 16 is then almost zero , which avoids any danger especially with regard to a rescue or maintenance team. Preferably, when the installation 10 comprises several electrical boxes 23, the phase line 32 of the control circuit is connected to all the housings 23, so that a single member 35, 36, 38 for stopping the the supply of the load circuit 14 (including a single emergency stop button 35) can place the switching means 26 of all the housings 23 in their second configuration.

If, during a disaster in the building, the emergency stop button 35 has been actuated, the installation 10 can be reactivated at the end of the disaster by resetting this push-button 35, this action alone The arrangement in the housing 23, on the one hand, means CC1, CC1, CC3 for short-circuiting the current generating means 12 and on the other hand, switching means 26 is particularly advantageous. Indeed, this housing 23 is placed near the photovoltaic modules 16 since it also contains the means 24 for connecting these modules in series. Therefore, the means simultaneously realizing the isolation of the modules 16 with respect to the charging circuit 14 and the short-circuiting of these modules 16 are placed close to the modules 16, which shortens the length of the short circuit circuits by the same amount.

In a variant, the short-circuiting means CC1, CC2, CC3 and the switching means 26 could be arranged in electrical boxes comprising means for electrically connecting the modules 16 in parallel. Of course, an electrical installation according to the invention could comprise a different number of photovoltaic modules 16 than those mentioned in the example.

Claims (10)

REVENDICATIONS1. Electrical installation comprising means (12) for generating direct current comprising at least one photovoltaic module (16) for supplying a charging circuit (14), characterized in that it comprises means (CC1, CC2, CC3) for in a short-circuit of the generating means (12) and switching means (26) of the generating means (12) between a first configuration providing the supply of the load circuit (14) and a second configuration ensuring the the isolation of the generator means (12) with respect to this charging circuit (14) and the activation of the means (CC1, CC2, CC3) for short-circuiting the generating means (12). 15 2. Installation according to claim 1, wherein the means (26) for switching the generating means (12) comprise relay means (RI, R2, R3) controlled by an electrical control circuit (30), the first configuration of the switching means (26) being imposed by a powered state of the control circuit (30) and the second configuration of the switching means (26) being imposed by a non-powered state of the control circuit. 3. Installation according to claim 2, wherein the relay means (RI, R2, R3) are electromechanical type, the control circuit (30) forms a supply circuit for means (B1, B2, B3) forming electromagnets of electromechanical relay means (R1, R2, R3). 25 4. Installation according to claim 2 or 3, wherein the control circuit (30) comprises opening means of the control circuit (30) having manual (35, 36) or automatic (38) of the power supply of the charging circuit (14). 5. Installation according to claim 4, wherein the opening means 30 of the control circuit (30) comprise manual control means (35) for emergency stop of the supply of the load circuit (14), for example of the push button type. 6. Installation according to claim 4 or 5, wherein the opening means of the control circuit (30) comprise manual control means (36) for non-emergency stop of the supply of the charging circuit (14). for example for maintenance purposes of the charging circuit (14). 2956533 -10- 7. Installation according to any one of claims 4 to 6, wherein the opening means of the control circuit (30) comprise means forming a differential circuit breaker (38). 8. Installation according to any one of the preceding claims, comprising at least two photovoltaic modules (16) intended to feed a charging circuit (14) and an electrical connection device (22) comprising means (24) for electrical connection of these modules (16) in series, the means (CC1, CC2, CC3) for short-circuiting the generator means (12) and the switching means (26) of the generator means (12). 9. An electrical connection device for connecting, on the one hand, direct current generating means (12) comprising at least two photovoltaic modules (16) to, on the other hand, a charging circuit (14), this device (23) comprising means (24) for the electrical connection in series of two photovoltaic modules (16), characterized in that it comprises means (CC1, CC2, CC3) for short-circuiting the generating means (12). ), and switching means (26) of the generating means (12) between a first configuration ensuring the supply of the charging circuit (14), and a second configuration ensuring both the isolation of the generating means (12). ) with respect to this charging circuit (14) and the activation of means (CC1, CC2, CC3) for short-circuiting the generating means (12). 10. Device according to claim 9, comprising a housing (23) in which are housed: the means (24) of electrical connection in series of two photovoltaic modules (16), the means (CC1, CC2, CC3) of short-circuit generator means (12), and - means (26) switching generator means (12).