FR3076670A1 - POWER SUPPLY NETWORK AND METHOD OF CONTROLLING THE SAME - Google Patents

Abstract

An electrical power supply network (1) comprising a power line (20) configured to be connected between first and second power sources (S1, S2), the power line (20) comprising a plurality of meshes (2, 4) , 6, 8), a plurality of bars (10, 12, ... 18) forming nodes of the supply network (1) and a plurality of circuit breakers (22, 24, ... 36), the meshes ( 2, 4, 6, 8) being connected one after the other by the plurality of bars (10, 12, ... 18), each mesh (2, 4, 6, 8) comprising two ends each end being electrically connected by a respective circuit breaker (22, 24, ... 36) to an adjacent bar (10, 12, ... 18), each circuit breaker (22, 24, ... 36) is selectively configurable : - in an unlocked configuration, or - in a locked configuration.

Description

Power supply network and associated control method

The present invention relates to a power supply network. The invention also relates to a method for controlling such a network. For example, the power network is a power network of a mobile vehicle or of several mobile vehicles. In another example, the supply network is an electrical network intended to supply industrial sites.

In this document, a power supply network is preferably a three-phase network, more preferably a medium voltage network, typically between 1 kV and 50 kV, more particularly between 11 kV and 33 kV.

Generally, a power supply network consists of nodes and meshes, a mesh electrically connecting two nodes.

We are considering here an application in which a client of the operator of the power supply network supplies electrical power to equipment connected to the nodes of a network. The network is powered by two power sources. A node is, for example, a busbar internal to a medium-voltage switchboard, also known as a "busbar" in English.

The meshes are for example power cables. A cable generally has a long length, for example of the order of a kilometer or more.

During maintenance of a mesh or detection of a failure of a mesh, the mesh concerned is electrically isolated from the rest of the supply network. To isolate the mesh, a reconfiguration of the supply network is carried out.

By reconfiguration, it is understood that the power supply of at least one node is alternated from one of the two power sources to the other power source.

However, the power supply networks of the aforementioned type and the associated control methods are not entirely satisfactory.

Indeed, the security of the power supply network is not satisfactory, especially during a reconfiguration of the network. In particular, a node is likely to be supplied by the two power sources at the same time, the two sources then being in parallel. As a result, the power network becomes electrically unstable.

There is therefore a need for a power supply network which allows a reconfiguration of the power supply network in complete safety, preventing a supply of a node simultaneously by the two power sources. To this end, the electrical supply network comprises an electrical line, configured to be connected between first and second power sources, the first and second power sources being configured to apply a high voltage level to the electrical line. , the power line comprising a plurality of meshes, a plurality of bars forming nodes of the supply network and a plurality of circuit breakers, the meshes being connected one after the other by the plurality of bars, each mesh comprising two ends, each end being electrically connected by a respective circuit breaker to an adjacent bar, each circuit breaker being configured to be in an open position or in a closed position, the supply network further comprising, associated with each mesh, a pair of relays in communication with each other, each relay being associated with the u n of the respective circuit breakers connected to the mesh, each relay being configured to drive the associated circuit breaker, each circuit breaker being selectively configurable: - in an unlocked configuration, allowing switching of the position of the circuit breaker from the open position to the closed position, or - in a locked configuration, preventing any switching of the circuit breaker position from the open position to the closed position, each relay being configured to acquire a value of a voltage level on a local bar, to which the associated circuit breaker is connected, and to acquire a value of the voltage level on a remote bar, to which the circuit breaker associated with the other relay of the pair of relays is connected, each relay being further configured to acquire the position of the circuit breaker associated with said relay, and to acquire the position of the circuit breaker associated with the other relay in the pair relay, each relay being configured to configure the circuit breaker associated with said relay in the locked configuration, if: - the associated circuit breaker is in the open position, - the high voltage level is measured on the local bar, - the high voltage level is measured on the remote bar, and - the circuit breaker associated with the other relay in the relay pair is in the closed position.

Such an electrical supply network makes it possible in particular to prevent the first and second power sources from being connected in parallel. Indeed, at the end of a manual or automatic opening of a circuit breaker of a mesh, for example for maintenance purposes or during a reconfiguration of the network, a closing, automatic or manual, of this circuit breaker is prevented if such a closure leads to putting the first source and the second source in parallel. Thus, at least one circuit breaker among the circuit breakers interposed between the two sources is open, so as to isolate the two power sources electrically, so that no node can be powered simultaneously by the two power sources.

In addition, such a power supply network is decentralized secure. The decentralized control, implemented by the relays of the power supply network, thus ensures the electrical separation of the first and second power source. Consequently, the power supply network according to the invention does not require any central controller to maintain electrical separation between the first and second power sources.

According to other characteristics of the electrical supply network according to the invention, taken in isolation or in all technically possible combinations: - each relay is, moreover, configured to configure the circuit breaker associated with said relay in the locked configuration if: + the associated circuit breaker is in the open position, and + at least one measurement of the voltage level measurements on the local busbar and on the remote busbar is not validated; - each circuit breaker is configured to be switched to the open position manually; - each relay is configured to determine the voltage level of the local bus; - each relay of a pair of relays is configured to transmit the voltage of the corresponding local busbar to the other relay of the pair of relays. - each relay of a pair of relays is configured to transmit to the other relay of the pair of relays the position of the circuit breaker associated with said relay; - each bar is configured to electrically power a mobile vehicle; - each bar is configured to electrically supply one or more industrial sites; - each relay is also able to configure the circuit breaker associated with said relay in the unlocked configuration, if: + the low voltage level is measured on the local bar, or + the low voltage level is measured on the remote bar, or + the circuit breaker associated with the other relay in the relay pair is in the open position. The invention also relates to a method for controlling a power supply network, said power network comprising an electric line connected between first and second power sources, the first and second power sources applying to the power line a high voltage level, the power line comprising a plurality of meshes, a plurality of bars forming nodes of the supply network and a plurality of circuit breakers, the meshes being connected one after the other by the plurality of bars, each mesh comprising two ends, each end being electrically connected by a respective circuit breaker to an adjacent bar, each circuit breaker being configured to be in an open position or in a closed position, the supply network further comprising , associated with each mesh, a pair of relays in communication with each other , each relay being associated with a respective circuit breaker connected to the mesh, each relay being configured to drive the associated circuit breaker, each circuit breaker being selectively configurable: - in an unlocked configuration, authorizing switching of the position of the circuit breaker from the open position to the closed position, or - in a locked configuration, preventing any switching of the position of the circuit breaker from the open position to the closed position, the method comprising: - a first step of detecting a position of a given circuit breaker of the plurality of circuit breakers, - a first step of acquisition, by the relay associated with the circuit breaker, of a value of a voltage level on a local bus to which said circuit breaker is connected, - a second step of acquisition, by the associated relay at the circuit breaker, a value of the voltage level on a remote bar to which is connected the circuit breaker associated with the other relay of the pair of relays, - a second step of detecting the position of the circuit breaker associated with the other relay of the pair of relays, - a step of configuring the circuit breaker in the locked configuration, implemented by the relay associated with the circuit breaker if: + the circuit breaker is in the open position, + the high voltage level is measured on the local busbar, + the high voltage level is measured on the remote busbar, and + the associated circuit breaker to the other relay in the relay pair is in the closed position. Other aspects and advantages of the invention will appear on reading the description which follows, given by way of example and made with reference to the appended drawings, in which: - Figure 1 is a general schematic representation of the network of power supply according to an initial configuration, - Figure 2 is a general schematic representation of the power supply network according to a first transition configuration, - Figure 3 is a general schematic representation of the power supply network according to a second transition configuration , - Figure 4 is a general schematic representation of the power supply network according to a final configuration, and - Figure 5 is a flowchart of a control method.

Figures 1 to 4 illustrate a power supply network 1 according to an embodiment of the invention.

The supply network 1 comprises a plurality of meshes 2, 4, 6, 8, a plurality of bars 10, 12, 14, 16, 18 forming nodes of the supply network 1, and a plurality of circuit breakers 22, 24 , 26, 28, 30, 32, 34, 36.

Each bar 10, 12, ... 18 is configured to electrically supply user equipment, not shown, such as a mobile vehicle.

The power network 1 is connected between first and second power sources S1, S2, located at each end of the network.

Meshes 2, 4, 6, 8 are connected in series with each other by means of bars 12, 14, 16 and 18.

In particular, each mesh 2, 4, 6, 8 comprises two ends, each electrically connected by a circuit breaker 22, 24, ... 36 to an adjacent bar,

In addition, each end link 2, 8 is electrically connected, via a circuit breaker 22, 36 and a bar 10, 18, to one of the power sources S1, S2.

In the illustrated embodiment, the supply network 1 has four meshes 2, 4, 6, 8 and five bars 10, 12, 14, 16, 18.

In this example, the supply network 1 therefore forms an electrical line 20, also called an electrical artery with bilateral supply. If the two sources are geographically close to each other, the power line 20 forms a loop.

The connection between the end of a mesh 2, 4, 6, 8 and a bar 10, 12, ... 18 is made through a circuit breaker 22, 24, 26, 28, 30, 32, 34 , 36 which is a switch, which can either be in an open position, symbolized by a line in the figures, or in a closed position, symbolized by a cross in Figures 1 to 4.

Each circuit breaker 22, 24, 26, 28, 30, 32, 34, 36 is capable of being switched from the open position to the closed position, and from the closed position to the open position, for example manually (ie by an operator) , and / or automatically.

Thus, the first link 2 is connected via a first circuit breaker 22 to the bar 10 and by a second circuit breaker 24 to the bar 12. The second link 4 is connected via a first circuit breaker 26 to the bar 12 and by a second circuit breaker 28 to the bar 14. The third mesh 30 is connected via a first circuit breaker 30 to the bar 14 and by a second circuit breaker 32 to the bar 16. Finally, the fourth mesh 40 is connected via a first circuit breaker 34 to the bar 16 and by a second circuit breaker 36 at the busbar 18. For example, in FIG. 1, the circuit breakers 22, 24, 26, 28, 34, 36 are closed and the circuit breakers 30 and 32 are open.

The first bar 10 is connected to a terminal of the first power source S1 of electrical power, the other terminal of the first power source S1 being connected to a reference potential of the power network 1 (not shown in the figures).

The fifth bar 18 is connected to a terminal of the second power source S2 of electrical power, the other terminal of the second power source S2 being connected to a reference potential of the power network 1 (not shown in the figures).

Each circuit breaker 22, 24, ... 36 is selectively configurable in an unlocked configuration, allowing switching of the position of the circuit breaker 22, 24, ... 36 from the open position to the closed position or in a locked configuration, preventing any switching of the position of the circuit breaker 22, 24, ... 36 from the open position to the closed position.

The supply network 1 further comprises a plurality of relays 50, 52, 54, 56, 58, 60, 62, 64. Each relay 50, 52, ... 64 is for example a relay of the type 87L according to ANSI / IEEE C37.2. Each relay 50, 52, ... 64 is associated with a circuit breaker 22, 24, ... 36 respectively.

Two relays 50, 52, ... 64 respectively form a pair 70, 72, 74, 76 of relays. Each pair 70, 72, 74, 76 of relays is associated with a mesh 2, 4, 6, 8 respectively. The two relays 50, 52, ... 64 of a pair 70, 72, 74, 76 of relays are configured to be in communication with one another by means of a link 80, 82, 84, 86 dedicated, for example an optical fiber connecting the two relays to each other.

Each circuit breaker 22, 24, ... 36 is associated with a local bus and a remote bus. The local bar is the bar 10, 12, ... 18 to which the circuit breaker 22, 24, ... 36 is connected, associated with a relay 50, 52, ... 64 of a pair 70, 72, 74 , 76 relay considered. The remote bar is the bar 10, 12, ... 18 to which is connected the circuit breaker 22, 24, ... 36 associated with the other relay 50, 52, ... 64 of the pair 70, 72, 74 , 76 relay considered.

Likewise, each relay 50, 52, ... 64 of a pair 70, 72, 74, 76 of relays is associated with a local bar and a remote bar. The local bar is the bar 10, 12, ... 18 to which the circuit breaker 22, 24, ... 36 connected to this relay is connected. The remote bar is the bar 10, 12, ... 18 to which is connected the circuit breaker 22, 24, ... 36 associated with the other relay of the pair 70, 72, 74, 76 of relay considered.

In the example of FIGS. 1 to 4, the local bar associated with the circuit breaker 22 and the relay 50 is the bar 10, and the remote bar associated with the circuit breaker 22 and the relay 50 is the bar 12. The local bar associated with the circuit breaker 24 and at relay 52 is the bar 12 and the remote bar associated with the circuit breaker 24 and at relay 52 is the bar 10. The local bar associated with the circuit breaker 26 and at relay 54 is the bar 12 and the remote bar associated with the circuit breaker 26 and the relay 54 is the bar 14. The local bar associated with the circuit breaker 28 and the relay 56 is the bar 14 and the remote bar associated with the circuit breaker 28 and the relay 56 is the bar 12. The local bar associated with the circuit breaker 30 and the relay 58 is the bus 14 and the remote bus associated with the circuit breaker 30 and the relay 58 is the bus 16. The local bus associated with the circuit breaker 32 and the relay 60 is the bus 16 and the remote bus associated with the circuit breaker 32 and the relay 60 is the bar 14. The local bar e associated with circuit breaker 34 and relay 62 is bar 16 and the remote bar associated with circuit breaker 34 and relay 62 is bar 18. The local bar associated with circuit breaker 36 and relay 64 is bar 18 and the associated remote bar at circuit breaker 36 and relay 64 is bar 16.

Each relay 50, 52, ... 64 has a programming capacity. For example, the MiCOM Agile P543-P546 relay from GE Grid Solutions has such programming capacity.

Each relay 50, 52, ... 64 is thus adapted to configure the circuit breaker 22, 24, ... 36 associated with this relay selectively in the locked configuration or in the unlocked configuration.

Preferably, each relay 50, 52, ... 64 is further configured to switch the circuit breaker 22, 24, ... 36 associated with this relay between the open position and the closed position, by sending a control signal by a C connection.

Each relay 50, 52, ... 64 of a pair 70, 72, 74, 76 of relay considered is, moreover, configured to acquire the position of the circuit breaker 22, 24, ... 36 associated with relay 50, 52 , ... 64 and configured to transmit to the other relay 50, 52, ... 64 of the pair 70, 72, 74, 76 of relay considered the position of the circuit breaker 22, 24, ... 36 associated with the relay 50, 52, ... 64.

Each relay 50, 52, ... 64 is, moreover, configured to acquire the position of the circuit breaker associated with the other relay 50, 52, ... 64 of the pair 70, 72, 74, 76 of relay, transmitted via link 80, 82, 84, 86 via this other relay 50, 52, ... 64.

Each relay 50, 52, ... 64 is further configured to acquire a value of a voltage level on the local bar associated with this relay.

Each relay 50, 52, ... 64 is notably connected to a voltage sensor making it possible to measure the voltage on the local bar, that is to say the bar 10, 12, ... 18 at which is connected the circuit breaker 22, 24, ... 36 associated with the relay.

In the example of FIGS. 1 to 4, the voltage sensor is symbolized by an isolation transformer 90, 92, 94, 96, 98, 100, 102, 104 between a bar 10, 12, ... 18 and a relay 50, 52, ... 64.

Each relay 50, 52, ... 64 is preferably suitable for periodically updating the value of a voltage level variable on the local bar, for example taking a value "0" when the bar 10, 12,. .. 18 is not supplied, and the value "1" when the bar 10, 12, ... 18 is supplied, that is to say brought to the voltage of the first source S1 or of the second source S2.

By acquiring the value of the voltage level on the local bar, it is understood to determine the voltage level of the local bar by measurement.

Each relay 50, 52, ... 64 of a relay pair 70, 72, 74, 76 is further configured to transmit to the other relay 50, 52, ... 64 of the pair 70, 72 , 74, 76 relay the voltage level of the local busbar of the associated circuit breaker 22, 24, ... 36, by the connection 80, 82, 84, 86.

Each relay 50, 52, ... 64 is further configured to acquire the value of the voltage level on a remote bar, transmitted via the link 80, 82, 84, 86 by the other relay 50, 52,. .. 64 of the relay pair 70, 72, 74, 76.

Each relay 50, 52, ... 64 is also able to configure the circuit breaker 22, 24, ... 36 associated with the relay 50, 52, ... 64 considered in the locked configuration, if the following conditions are fulfilled: - the associated circuit breaker 22, 24, ... 36 is in the open position, - the high voltage level is measured on the local bar 10, 12, ... 18, - the high voltage level is measured on the bar 10, 12, ... 18 remote, and the circuit breaker 22, 24, ... 36 associated with the other relay 50, 52, ... 64 of the pair 70, 72, 74, 76 of relay is in closed position.

Such locking makes it possible to avoid closing of the circuit breaker 22, 24, ... 36 which may have the effect of placing the sources S1, S2 in parallel.

Each relay 50, 52, ... 64 is also able to configure the circuit breaker 22, 24, ... 36 associated with the relay 50, 52, ... 64 considered in the unlocked configuration, if: - the level of low voltage is measured on bar 10, 12, ... 18 local, or - the low voltage level is measured on bar 10, 12, ... 18 remote, or - circuit breaker 22, 24, .. 36 associated with the other relay 50, 52, ... 64 of the pair 70, 72, 74, 76 of the relay is in the open position.

In Figures 1 to 4, several configurations of the supply network 1 are shown. The continuation of Figures 1 to 4 illustrates a reconfiguration of the power supply network 1.

Each bar 10, 12, ... 18 is configured to be supplied either by the first power source S1 or by the second power source S2.

The possibility of modifying the power supply of a busbar 10, 12, ... 18 from one of the first and second power sources S1, S2 to the other constitutes a redundancy function of the power supply network 1.

To avoid placing the two power sources S1, S2 in parallel, the circuit breakers 22, 24, ... 36 of a sectional mesh 2, 4, 6, 8 are in the open position. The choice of the sectioning mesh results, for example, from an optimization of the supply network 1 as a function of the connected equipment and their electrical power requirements. In another example, a mesh 2, 4, 6, 8 in which maintenance is carried out, is chosen as a sectioning mesh and electrically separated from the first and second power source S1, S2.

According to an initial configuration, shown in FIG. 1, the mesh 6 represents the sectioning mesh. Through first and second transition configurations, shown in Figures 2 and 3, a final configuration, shown in Figure 4, is obtained. In the final configuration, the mesh 4 represents the sectioning mesh. The configurations shown in Figures 1 to 4 are described in more detail below.

In Figure 1, representing the power network 1 according to the initial configuration, the circuit breakers 30 and 32 are in the open position. Therefore, the supply network 1 is subdivided into a first segment which is supplied by the first supply source S1, and a second segment which is supplied by the second supply source S2, separated by the sectioning mesh 6. In the example of FIG. 1, the bar 10, 12 and 14 is supplied by the first power source S1 and the bar 16 and 18 by the second power source S2. The sectionalizing mesh 6, which is not supplied, has an indefinite potential.

The configuration shown in FIG. 1 being described above, in the description which follows, only differences in configuration compared to the configuration shown in FIG. 1 are highlighted.

In the example of FIG. 2, the supply network 1 according to the first transition configuration is shown.

The circuit breaker 28 is in the open position. For example, the circuit breaker 28 is configured to be tilted to the open position manually by an operator. In another example, the circuit breaker 28 is configured to be controlled automatically by the relay 56 being connected to a modification system, not shown, of the supply network 1. The circuit breaker 28 is for example controlled in the open position, in particular in order to preparing a subsequent electrical separation of the mesh 4 of the first and second power source S1, S2.

The bar 14 is thus not supplied. Equipment connected to the bar 14 is no longer supplied. To replenish the bar 14, for example, the circuit breakers 30 and 32 are switched, automatically or manually, in the closed position and the bar 14 thus supplied by the second power source S2, as illustrated in FIG. 3.

In the example of FIG. 3, the supply network 1 according to the second transition configuration is shown.

The circuit breakers 30 and 32 are in the closed position and only the circuit breaker 28 is in the open position.

The circuit breaker 28 is associated with relay 56, of the pair 72 of relays.

The local bar of relay 56, that is to say the bar 14, supplied by the second power source S2, is at a high voltage level.

The remote bar of relay 56, that is to say the bar 12, supplied by the first power source S1, is at a high voltage level.

In addition, the circuit breaker 26 associated with the other relay 54 of the pair 72 of relays is in the closed position.

In such a configuration, in particular, the relay 56 is able to acquire the value of the voltage level on the local bar 14, which in this configuration is a high voltage level.

Furthermore, the relay 56 is able to acquire the value of the voltage level on the remote bar 12, which in this configuration is a high voltage level. For example, the relay 56 is able to receive this value from the other relay 54, measured by this other relay 54 and transmitted via the link 82.

The relay 56 is also configured to acquire the position of the circuit breaker 28 associated with the relay 56, which in this configuration is the open position, and to acquire the position of the circuit breaker 26 associated with the other relay 54 of the pair 72 of relays, by example measured by this other relay 54 and transmitted via the link 82.

In such a configuration, the circuit breaker 28 associated with the relay 56 is in the open position, the circuit breaker 26 associated with the other relay 54 of the pair 72 of relays in the closed position, the high voltage level being measured on the local bar 14, and the high voltage level being measured on the remote bar 12, the relay 56 is able to configure the circuit breaker 28 associated with this relay 56 in the locked configuration.

Since closing of the circuit breaker 28 is not authorized, the first and second power sources S1, S2 are not electrically connected and cannot be put in parallel.

In the example of Figure 4, the circuit breakers 26 and 28 are in the open position and the circuit breakers 22, 24, 30, 32, 34, 36 are in the closed position. Mesh 4 is not supplied by the first and second power sources S1, S2. The local bar 14 of the relay 56 is in high voltage level as well as the remote bar 12 of the relay is in high voltage level. In addition, the circuit breaker 26 associated with the other relay 54 of the pair 72 of relays is in the open position. The relay 56 is then configured to configure the circuit breaker 28 in the unlocked configuration, a closing of the single circuit breaker 28 no longer causing the first and second power sources S1, S2 to be connected in parallel.

The operation of the supply network 1 will now be described with reference to FIG. 5. More particularly, the operation during the reconfiguration of the supply network 1 is described. By way of example, the supply network 1 is in the second transition configuration shown in FIG. 3 at the start of a control process described below.

During an initial step 200, the position of a given circuit breaker 22, 24, ... 36 is detected, in particular by the relay associated with this circuit breaker. For example, the position of the circuit breaker 28, in the example of Figure 3 the open position, is detected by the relay 56 associated with the circuit breaker 28.

In the next step 210, a value of the voltage level on the local bar to which the given circuit breaker is connected is acquired. Step 210 is implemented by the relay 50, 52, ... 64 associated with the given circuit breaker 22, 24, ... 36. In the example of FIG. 3, a value of the voltage level on the bar 14, which is a high voltage in this example, is acquired by the relay 56 associated with the circuit breaker 28.

In the next step 220, a value of the voltage level on the remote bar to which the circuit breaker 22, 24, ... 36 is connected associated with the other relay 50, 52, ... 64 of a pair 70, 72, 74, 76 of given relay is acquired. Step 220 is implemented by the relay 50, 52, ... 64 associated with the circuit breaker 22, 24, ... 36 of the other relay 50, 52, ... 64 of the pair 70, 72, 74, 76 of given relay. In the example of FIG. 3, a value of the voltage level on the bar 12, which is a high voltage in this example, is acquired by the relay 54 associated with the circuit breaker 26.

During the next step 230, the position of a circuit breaker 22, 24, ... 36 associated with the other relay 50, 52, ... 64 of the pair 70, 72, 74, 76 of given relay is detected. For example, the position of the circuit breaker 26, which in the example of Figure 3 is the closed position, is detected by the relay 54 associated with the circuit breaker 26.

During the final step 240, the relay 50, 52 ... 64 associated with the given circuit breaker 22, 24, ... 36 configures this circuit breaker in the locked configuration, if all of the following conditions are satisfied during the execution of steps 200 to 230 of the control method: - During the initial step 200, the open position of the given circuit breaker 22, 24, ... 36 is detected. - During step 210, a value corresponding to the high voltage level is measured on the local bar of the circuit breaker 22, 24, ... 36 given as well as (step 220) on the remote bar of the circuit breaker 22, 24,. .. 36 given. - During step 230, the relay 50, 52 ... 64 acquires, in particular from the other relay of the pair of relays, the closed position of the circuit breaker 22, 24, ... 36 associated with the other relay 50, 52, ... 64. By way of illustration, in the configuration of FIG. 3, the circuit breaker 28 is in the open position, the circuit breaker 26 is in the closed position and the local bar 14 as well as the bar 12 distant from the circuit breaker 28 are at the high voltage level. The relay 56 thus configures the circuit breaker 28 in the locked configuration, preventing any closing of this circuit breaker 28.

According to one embodiment, the or each relay 50, 52, ... 64 is also able to configure the circuit breaker 22, 24, ... 36 associated with this relay in the locked configuration if the circuit breaker 22, 24, .. 36 associated is in the open position and at least one measurement of the voltage level measurements on the local bar and on the remote bar of the given circuit breaker 22, 24, ... 36 is not validated. For example, in the configuration shown in FIG. 3, the circuit breaker 28 is locked in the open position if the voltage level measurement on the bar 14 and / or on the bar 12 is not validated.

Preferably, the tension on a bar 10, 12, ... 18 is validated or not validated independently of a result of measurement of tensions at the bar 10, 12, ... 18.

For example, the voltage level is considered valid until an invalidation alarm has been issued. The alarm is generated by monitoring the operation of the voltage sensor, for example using fuses or micro-circuit breakers. The voltage level is validated if a voltage at a primary device, such as a sensor simplified by capacitive effect, and a voltage at a secondary device of the voltage sensor are consistent. For example, if the voltage determined at the first sensor device is too low or too high, the alarm is triggered and the voltage level is not validated.

According to one embodiment, during the final step 240, or following the final step 240, the relay 50, 52, ... 64 is able to configure the associated circuit breaker 22, 24, ... 36 in the unlocked configuration, or in maintaining the associated circuit breaker 22, 24, ... 36 in the unlocked configuration, if applicable, if at least one of the following conditions is met: - During step 210, a voltage level low is measured on the local bar of the circuit breaker 22, 24, ... 36 associated with the relay; - During step 220, a low voltage level is measured on the remote bar of the circuit breaker 22, 24, ... 36 associated with the relay. - During step 230, the open position of the circuit breaker 22, 24, ... 36 associated with the other relay 50, 52, ... 64 of the pair 70, 72, 74, 76 of given relay is detected .

Data determined or acquired during steps 200 to 230 are taken into account in the final step 240. This is illustrated by broken lines in FIG. 5 between each step 200 to 230 and the final step 240.

Alternatively, steps 200 to 230 are executed in another order before the final step 240. For example, the steps are executed in order 200-230-220-210. Those skilled in the art will understand that the reconfiguration of the supply network 1 is implemented automatically, for example by a controller of the supply network 1, or manually by an operator, by opening and / or closing the circuit breakers 22, 24 , ... 36.

Claims (10)

1.-electrical power network (1), said power network (1) comprising an electrical line (20), configured to be connected between first and second power sources (S1, S2), the first and second power sources (S1, S2) being configured to apply a high voltage level to the power line (20), the power line (20) comprising a plurality of meshes (2, 4, 6, 8), a plurality of bars (10, 12, ... 18) forming nodes of the supply network (1) and a plurality of circuit breakers (22, 24, ... 36), the meshes (2, 4, 6, 8) being connected one after the other by the plurality of bars (10, 12, ... 18), each mesh (2, 4, 6, 8) comprising two ends, each end being electrically connected by a respective circuit breaker (22, 24, ... 36) to an adjacent busbar (10, 12, ... 18), each circuit breaker (22, 24, ... 36) being configured to be in an open position te or in a closed position, the supply network (1) further comprising, associated with each mesh (2, 4, 6, 8), a pair (70, 72, 74, 76) of relays in communication l ' one with the other, each relay (50, 52, ... 64) being associated with one of the respective circuit breakers (22, 24, ... 36) connected to the mesh (2, 4, 6, 8) , each relay (50, 52, ... 64) being configured to drive the associated circuit breaker (22, 24, ... 36), characterized in that each circuit breaker (22, 24, ... 36) is selectively configurable : - in an unlocked configuration, authorizing switching of the circuit breaker position (22, 24, ... 36) from the open position to the closed position, or - in a locked configuration, preventing any switching of the circuit breaker position ( 22, 24, ... 36) from the open position to the closed position, each relay (50, 52, ... 64) being configured to acquire a value of a voltage level on a bar (10, 1 2, ... 18) local, to which the associated circuit breaker (22, 24, ... 36) is connected, and to acquire a value of the voltage level on a remote bar (10, 12, ... 18) , to which is connected the circuit breaker (22, 24, ... 36) associated with the other relay (50, 52, ... 64) of the pair (70, 72, 74, 76) of relays, each relay (50, 52, ... 64) being further configured to acquire the position of the circuit breaker associated with said relay, and to acquire the position of the circuit breaker associated with the other relay of the pair (70, 72, 74, 76) of relay, and in that each relay (50, 52, ... 64) is configured to configure the circuit breaker (22, 24, ... 36) associated with said relay in the locked configuration, if: the circuit breaker (22, 24 , ... 36) associated is in the open position, - the high voltage level is measured on the local bar (10, 12, ... 18), the high voltage level is measured on the bar (10, 12, ... 18) remote, and the circuit breaker (22, 24, ... 36) associated with the other relay (50, 52, ... 64) of the pair (70, 72, 74, 76) of the relay is in the closed position. 2. - Supply network (1) according to claim 1, in which each relay (50, 52, ... 64) is, moreover, configured to configure the associated circuit breaker (22, 24, ... 36) said relay (50, 52, ... 64) in the locked configuration if: the associated circuit breaker (22, 24, ... 36) is in the open position, and at least one measurement of the voltage level measurements on the bar (10, 12, ... 18) local and on the remote bar (10, 12, ... 18) is not validated, a voltage level measurement being validated if a voltage measured at a primary device and a voltage measured to a secondary device of an associated voltage sensor are consistent. 3. - Power network (1) according to claim 1 or 2, wherein each circuit breaker (22, 24, ... 36) is configured to be switched to the open position manually. 4. - Supply network (1) according to any one of claims 1 to 3, in which each relay (50, 52, ... 64) is configured to determine the voltage level of the bar (10,12 , ... 18) local. 5. - Supply network (1) according to claim 4, in which each relay (50, 52, ... 64) of a pair (70, 72, 74, 76) of relays is configured to transmit to the 'other relay (50, 52, ... 64) of the pair (70, 72, 74, 76) of relay the voltage level of the bar (10, 12, ... 18) corresponding local. 6. - Supply network (1) according to any one of claims 1 to 5, in which each relay (50, 52, ... 64) of a pair (70, 72, 74, 76) of relays is configured to transmit to the other relay (50, 52, ... 64) of the pair (70, 72, 74, 76) of relays the position of the circuit breaker (22, 24, ... 36) associated with said relay (50, 52, ... 64). 7, - Power supply network (1) according to any one of claims 1 to 6, wherein each bar (10, 12, ... 18) is configured to electrically power a mobile vehicle. 8. Power network (1) according to any one of claims 1 to 6, wherein each bar (10, 12, ... 18) is configured to electrically supply one or more industrial sites. 9. - Supply network (1) according to any one of claims 1 to 8, in which each relay (50, 52, ... 64) is further able to configure the circuit breaker (22, 24, .. 36) associated with said relay (50, 52, ... 64) in the unlocked configuration, if: - the low voltage level is measured on the local bar (10,12, ... 18), or - the level low voltage is measured on the remote bar (10, 12, ... 18), or - the circuit breaker (22, 24, ... 36) associated with the other relay (50, 52, ... 64) of the pair (70, 72, 74, 76) of relays is in the open position. 10, - Method for controlling a supply network (1), said supply network (1) comprising an electrical line (20) connected between first and second supply sources (S1, S2), the first and second power sources (S1, S2) applying a high voltage level to the power line (20), the power line (20) comprising a plurality of meshes (2, 4, 6, 8), a plurality of bars (10, 12, ... 18) forming nodes of the supply network (1) and a plurality of circuit breakers (22, 24, ... 36), the meshes (2, 4, 6, 8) being connected one after the other by the plurality of bars (10, 12, ... 18), each mesh (2, 4, 6, 8) comprising two ends, each end being electrically connected by a respective circuit breaker (22, 24, ... 36) to an adjacent bar (10, 12, ... 18), each circuit breaker (22, 24, ... 36) being configured to be in an open position or in a closed position e, the supply network (1) further comprising, associated with each mesh (2, 4, 6, 8), a pair (70, 72, 74, 76) of relays in communication with each other , each relay (50, 52, ... 64) being associated with one of the respective circuit breakers (22, 24, ... 36) connected to the mesh (2, 4, 6, 8), each relay (50 , 52, ... 64) being configured to drive the associated circuit breaker (22, 24, ... 36), characterized in that each circuit breaker (22, 24, ... 36) is selectively configurable: in an unlocked configuration , authorizing switching of the position of the circuit breaker (22, 24, ... 36) from the open position to the closed position, or in a locked configuration, preventing any switching of the position of the circuit breaker (22, 24, ... 36) from the open position to the closed position, and in that the method comprises: - a first step of detecting (200) a position of a given circuit breaker (22, 24, ... 36) of the plural é of circuit breakers (22, 24, ... 36), - a first acquisition step (210), by the relay (50, 52, ... 64) associated with the circuit breaker (22, 24, ... 36 ), of a value of a voltage level on a local bar (10,12, ... 18) to which said circuit breaker (22, 24, ... 36) is connected, - a second acquisition step (220), via the relay (50, 52, ... 64) associated with the circuit breaker (22, 24, ... 36), of a value of the voltage level on a bus (10, 12, ... 18) remote to which is connected the circuit breaker (22, 24, ... 36) associated with the other relay (50, 52, ... 64) of the pair (70, 72, 74, 76) of relays, a second step of detecting (230) the position of the circuit breaker (22, 24, ... 36) associated with the other relay (50, 52, ... 64) of the pair (70, 72, 74, 76) of relay, - a configuration step (240) of the circuit breaker (22, 24, ... 36) in the locked configuration, implemented by the relay (50, 52, ... 64) associated with the circuit breaker ( 22, 24, ... 36) if: o the circuit breaker (22, 24, ... 36) is in the open position, o the high voltage level is measured on the local bar (10, 12, ... 18), o the high voltage level is measured on the remote bar (10, 12, ... 18), and o the circuit breaker (22, 24, ... 36) associated with the other relay (50, 52, ... 64) of the pair ( 70, 72, 74, 76) of the relay is in the closed position.