Voltage sourced converter with semiconductor modules handling a DC current fault

The invention claimed is: 1. A Voltage Sourced Converter (VSC) for a High Voltage Direct Current (HVDC) power converter, the VSC being a Multi-level Modular Converter (MMC), the VSC comprising: a bridge circuit for each of one or more phases of an AC network, the bridge circuit having two arms, each arm connecting the supply to a pole of a DC terminal, wherein each arm of the bridge circuit has an inductance, a branch equivalent impedance, one or more semiconductor modules capable of being switched between an on-condition, in which a capacitor of the semiconductor module is in-line in the arm of the bridge circuit, and an off-condition, in which the capacitor is out of line; a DC current fault detection arrangement for detecting a fault arising within the VSC or at one or the other of the poles of the DC terminal; a built-in fault detector for detecting either AC faults or DC faults: and a controller responsive to the detection of any of the current faults by the DC current detection arrangement and/or the built-in fault detector for switching the one or more semiconductor modules in one of the arms of the bridge circuit to the on-condition, and the one or more semiconductor modules of the other arm of the bridge circuit to the off-condition, such that electrical energy stored in the capacitors and inductances is released in the form of an LC oscillation and the branch equivalent impedance can be maximized in order to minimize AC current through the VSC. 2. The Voltage Sourced Converter of claim 1 wherein the controller in response to the detection of the DC current fault, switches all the semiconductor modules in one of the arms of the bridge circuit to the on-condition and all the semiconductor modules of the other arm of the bridge circuit to the off-condition. 3. The Voltage Sourced Converter of claim 1 wherein the one or more semiconductor modules comprises a capacitor and semiconductor devices that perform the function of an Insulated Gate Bipolar Transistor (IGBT), wherein the semiconductor devices are operable for switching between the on-condition, in which the capacitor of the semiconductor module is in-line in the corresponding arm of the bridge circuit, and an off-condition, in which the capacitor is bypassed in the corresponding arm of the bridge circuit. 4. The Voltage Sourced Converter of claim 3 wherein each of the semiconductor devices comprises an integral inverse parallel diode. 5. The Voltage Sourced Converter of claim 1 wherein one or more semiconductor modules is placed between the DC terminal and one of a DC bus, DC connector, and another DC terminal. 6. A method for controlling current faults in a Voltage Sourced Converter (VSC) for a High Voltage Direct Current (HVDC) power converter, the VSC being a Multi-level Modular Converter (MMC), the VSC comprising a bridge circuit for each of one or more phases of an AC network, the bridge circuit having two arms, each arm connecting the supply to a pole of a DC terminal, each arm of the bridge circuit having one or more semiconductor modules capable of being switched between an on-condition, in which a capacitor of the semiconductor module is in-line in the arm of the bridge circuit, and an off-condition, in which the capacitor is out of line, the method comprising: detecting a DC current fault arising within the VSC or at one or the other of the poles of the DC terminal; detecting an AC current fault; and in response to the detection of the DC current fault and/or the AC current fault, switch the one or more semiconductor modules in one of the arms of the bridge circuit to the on-condition, and switch the one or more semiconductor modules of the other arm of the bridge circuit to the off-condition, such that electrical energy stored in the capacitors and inductances is released in the form of an LC oscillation and the branch equivalent impedance can be maximized in order to minimize AC currents through the VSC. 7. The method of claim 6 wherein, in response to the detection of the DC current fault, all of the semiconductor modules in one arm of each bridge circuit are turned on and all the semiconductor modules in the other arm of each bridge circuit are turned off. 8. The method of claim 6 , further comprising isolating a DC grid side from an AC side of the VSC to reduce a DC current due to the AC fault.