Voltage source converter with improved operation

The invention claimed is: 1. A voltage source converter having two DC terminals and a number of AC terminals for providing a number of phases of an AC voltage, the converter comprising: a number of director valves connected in series between the DC terminals, the director valves being provided in pairs, where each pair forms a valve phase leg comprising an upper valve phase arm and a lower valve phase arm, where a junction between the upper and lower valve phase arms of a valve phase leg provides a primary AC terminal for a corresponding AC phase; a number of multilevel cells connected in series between the DC terminals, the cells being grouped in waveshaper phase legs, where each waveshaper phase leg is connected in parallel with a corresponding valve phase leg and comprises an upper and a lower waveshaper phase arm, where a junction between the upper and lower waveshaper phase arms of a waveshaper phase leg provides a secondary AC terminal for a corresponding AC phase and is linked to the primary AC terminal of the corresponding valve phase leg, wherein the upper waveshaper phase arm of a waveshaper phase leg is configured to be operated in conjunction with the upper valve phase arm of the corresponding valve phase leg, and wherein the lower waveshaper phase arm of a waveshaper phase leg is configured to be operated in conjunction with the lower valve phase arm of the corresponding valve phase leg, for forming an AC waveform at least during steady state operation; and a controller configured to control each waveshaper phase leg and valve phase leg for forming a number of phases of an output AC voltage, where the voltage of one phase is formed on the primary and secondary AC terminals of a pair of valves and waveshaper phase legs through alternately operating the valve of the upper valve phase arm and the cells of the corresponding upper waveshaper phase arm with the valve of the lower valve phase arm and cells of the corresponding lower waveshaper phase arm, thereby one waveshaper phase arm in each phase is inactive with regard to waveshaping as an available waveshaper phase arm, wherein the controller is further configured to control at least one of the available waveshaper phase arms through controlling the waveshaper phase arm towards a target phase arm voltage using a control value that is based on a sum of absolute values of reference voltages used for waveshaping in the waveshaper phase legs. 2. The voltage source converter according to claim 1 , wherein the control value is based on a difference between a DC voltage value of the DC terminals and said sum of absolute values, where the DC voltage value is a difference between the voltages on the DC terminals. 3. The voltage source converter according to claim 1 , wherein the control unit is configured to control the valves of a valve phase leg to be turned on in a case of AC fault ride-through of a fault on an AC line connected to the AC terminal of the valve phase leg. 4. The voltage source converter according to claim 1 , wherein the controller is configured to turn off the valves after detection of a DC pole fault and keep the valves turned off until after fault clearance. 5. The voltage source converter according to claim 4 , where the controller is configured to also block the multilevel cells. 6. The voltage source converter according to claim 1 , wherein each director valve comprises at least one pair of anti-parallel thyristors and each waveshaper phase arm further comprises a commutation cell controllable to reverse-bias the director valve of the corresponding valve phase arm for controlling the corresponding valve phase arm to stop conducting current. 7. The voltage source converter according to claim 6 , wherein the number of the available phase arms is n and the controller when being configured to control the available waveshaper phase arms is configured to control a maximum of (n−1) of the available waveshaper phase arms. 8. The voltage source converter according to claim 6 , wherein the available phase arm is available in an availability period and the controller, when being configured to control the available waveshaper phase arm, is configured to perform said control after a start and before an end of the availability period. 9. The voltage source converter according to claim 6 , wherein the controller is configured to control a firing angle of the valve thyristors to reduce the DC voltage after detection of a DC pole fault. 10. The voltage source converter according to claim 6 , wherein the control value is based on a difference between a DC voltage value of the DC terminals and said sum of absolute values, where the DC voltage value is a difference between the voltages on the DC terminals, wherein the control unit is configured to control the valves of a valve phase leg to be turned on in a case of AC fault ride-through of a fault on an AC line connected to the AC terminal of the valve phase leg, and wherein the DC voltage value is scaled down. 11. The voltage source converter according to claim 10 , wherein the controller is configured to perform said control during reduced DC voltage operation. 12. The voltage source converter according to claim 1 , wherein the controller is configured to perform the control of the available waveshaper phase arms during steady state operation. 13. The voltage source converter according to claim 1 , wherein the controller is configured to perform said control of the available waveshaper phase arms during an AC fault handling mode in a case where a sum of rectified AC voltages fall. 14. A method of controlling a voltage source converter having two DC terminals and a number of AC terminals for providing a number of phases of an AC voltage, the converter comprising: a number of director valves connected in series between the DC terminals, the director valves being provided in pairs, where each pair forms a valve phase leg comprising an upper valve phase arm and a lower valve phase arm, where a junction between the upper and lower valve phase arms of a valve phase leg provides a primary AC terminal for a corresponding AC phase and a number of multilevel cells connected in series between the DC terminals, the cells being grouped in waveshaper phase legs, where each waveshaper phase leg is connected in parallel with a corresponding valve phase leg and comprises an upper and a lower waveshaper phase arm, where a junction between the upper and lower waveshaper phase arms of a waveshaper phase leg provides a secondary AC terminal for a corresponding AC phase and is linked to the primary AC terminal of the corresponding valve phase leg, wherein the upper waveshaper phase arm of a waveshaper phase leg is configured to be operated in conjunction with the upper valve phase arm of the corresponding valve phase leg, and wherein the lower waveshaper phase arm of a waveshaper phase leg is configured to be operated in conjunction with the lower valve phase arm of the corresponding valve phase leg, for forming of an AC waveform at least during steady state operation, the method comprising the steps of: controlling each waveshaper phase leg and valve phase leg for forming a number of phases of an output AC voltage, where the voltage of one phase is formed on the primary and secondary AC terminals of a pair of valves and waveshaper phase legs through alternately operating the valve of the upper valve phase arm and the cells of the corresponding upper waveshaper phase arm with the valve of the lower valve phase arm and cells of the corresponding lower waveshaper phase arm, thereby one waveshaper phase arm in each phase is inactive with regard to waveshaping as an avail