Protection for an HVDC network

The invention claimed is: 1. A method of protecting a high-voltage DC electrical network ( 1 ), the network comprising: high-voltage electrical lines ( 120 , 130 , 230 ); three interconnection nodes ( 10 , 20 , 30 ) each comprising: a common network interface comprising at least two controlled switches and exhibiting respective current interruption capabilities, the common network interface being connected to other interconnection nodes via two high-voltage lines connected to its two respective controlled switches, such that each high-voltage line is connected between two controlled switches at its ends; a local network interface; three local networks, connected to a local network interface of a respective interconnection node ( 10 , 20 , 30 ), each local network comprising: an MMC converter ( 16 , 26 , 36 ); a protection circuit connected between this MMC converter and the local network interface of its interconnection node, the protection circuit comprising first and second branches connected in parallel, the first branch including a first controlled switch ( 14 ) and a first short-circuit current limiter ( 15 ), the second branch including a second controlled switch ( 12 ) and a second short-circuit current limiter ( 13 ); the method comprising the steps for: initially maintaining the said first controlled switches ( 14 ) closed and the said second controlled switches ( 12 ) open; measuring the voltage on and the current in each of the said controlled switches of the common network interface; for each of the said controlled switches connected to one end of a high-voltage line, communicating at least the direction of the current flowing through this controlled switch, or a command to open the controlled switch situated at the other end of the high-voltage line, to the interconnection node comprising the controlled switch connected to the other end of this high-voltage line; each interconnection node connected to a faulty high-voltage line: identifies a fault on this high-voltage line on the basis of the current and of the voltage measured for its controlled switch connected to this faulty high-voltage line and on the basis of the direction of the current communicated for the controlled switch connected to the other end of this faulty high-voltage line, or on the basis of a command to open its controlled switch, and verifies that the current flowing through its controlled switch connected to this faulty high-voltage line is lower than the current interruption capability of this controlled switch and controls the opening of this controlled switch; then for each of the MMC converters ( 16 , 26 , 36 ), it is verified that the voltage measured on a controlled switch of its common network interface has exceeded a verification threshold, then the second controlled switch of its protection circuit is closed. 2. The method of protecting a high-voltage DC electrical network ( 1 ) as claimed in claim 1 , in which the said first and second short-circuit current limiters ( 13 , 15 , 23 , 25 , 33 , 35 ) are of the superconducting type, the method furthermore comprising the opening of the said first controlled switches ( 14 , 24 , 34 ) after the closing of the said second controlled switches ( 12 , 22 , 32 ). 3. The method of protecting a high-voltage DC electrical network as claimed in claim 1 , in which the said controlled switches of the common network interfaces of the protected electrical network each exhibit a current interruption capability PdC at least equal to Σ i=1 N Cl i , with N the number of MMC converters, and Cl i the limitation current of the first current limiter of the protection circuit of the MMC converter of index i. 4. The method of protecting a high-voltage DC electrical network ( 1 ) as claimed in claim 1 , in which the controlled switches of the common network interfaces of the electrical network are mechanical circuit breakers. 5. The method of protecting a high-voltage DC electrical network as claimed in claim 1 , in which the said verification voltage threshold for each MMC converter is equal to at least 70% of its nominal voltage. 6. The method of protecting a high-voltage DC electrical network as claimed in claim 1 , in which the said MMC converters are of the half-bridge type. 7. The method of protecting a high-voltage DC electrical network as claimed in claim 1 , comprising the following steps: for each of the said controlled switches connected to one end of a high-voltage line, communicating its measured voltage and current to the interconnection node comprising the controlled switch connected to the other end of this high-voltage line; identifying a fault on this high-voltage line on the basis of the current and of the voltage measured for its controlled switch connected to this faulty high-voltage line and on the basis of the current and of the voltage communicated for the controlled switch connected to the other end of this faulty high-voltage line. 8. A high-voltage DC electrical network ( 1 ), characterized in that it comprises: high-voltage electrical lines ( 120 , 130 , 230 ); three interconnection nodes ( 10 , 20 , 30 ) each comprising: a common network interface comprising at least two controlled switches and exhibiting respective current interruption capabilities, the common network interface being connected to other interconnection nodes via two high-voltage lines connected to its two respective controlled switches, such that each high-voltage line is connected between two controlled switches at its ends; a local network interface; three local networks, connected to a local network interface of a respective interconnection node ( 10 , 20 , 30 ), each local network comprising: an MMC converter ( 16 , 26 , 36 ); a protection circuit connected between this MMC converter and the local network interface of its interconnection node, the protection circuit comprising first and second branches connected in parallel, the first branch including a first controlled switch ( 14 ) and a first short-circuit current limiter ( 15 ), the second branch including a second controlled switch ( 12 ) and a second short-circuit current limiter ( 13 ); a control and monitoring circuit configured for: initially maintaining the said first controlled switches closed and the said second controlled switches open; measuring the voltage on and the current in each of the said controlled switches of the common network interface; for each of the said controlled switches connected to one end of a high-voltage line, communicating at least the direction of the current flowing through this controlled switch, or a command to open the controlled switch situated at the other end of the high-voltage line, to the interconnection node comprising the controlled switch connected to the other end of this high-voltage line; identifying a fault on this high-voltage line on the basis of the current and of the voltage measured for its controlled switch connected to this faulty high-voltage line and on the basis of the direction of the current communicated for the controlled switch connected to the other end of this faulty high-voltage line, or on the basis of a command to open its controlled switch, and verifying that the current flowing through its controlled switch connected to this faulty high-voltage line is lower than the current interruption capability of this controlled switch and controlling the opening of this controlled switch; then for each of the MMC converters ( 16 , 26 , 36 ), verifying that its voltage has exceeded a threshold and closing the second controlled switch of its protection circuit. 9. The high-voltage DC electrical network ( 1 ) as claimed in claim 8 ,