System and method for fault handling in a propulsion system for an electric vehicle

What is claimed is: 1. A propulsion system for an electric vehicle, the system comprising: a high voltage battery unit having a first high voltage battery connected in series with a second high voltage battery such that a nominal operating voltage of the high voltage battery unit is the sum of a voltage of the first high voltage battery and a voltage of the second high voltage battery; one or more power inverters arranged to connect the high voltage battery unit and the first high voltage battery to one or more electric machines, wherein the one or more power inverters and the one or more electric machines are configured to form a first and a second three-phase system; a propulsion system control unit configured to detect a fault in the first or the second three-phase system, wherein the power inverter of the faulty three-phase system is configured to operate in a safe pulse-off mode, where transistors of the power inverter of the faulty three-phase system are in an open state and switching of the transistors is stopped, if a back electromotive force, back-EMF, of the faulty three-phase system is lower than the operating voltage of the high voltage battery unit; and wherein the propulsion system control unit is configured to control the non-faulty three-phase system of the first and second three-phase system to provide field weakening current control to reduce the magnetic field in the faulty three-phase system. 2. The propulsion system according to claim 1 , wherein each of the one or more power inverters is configured to operate at a voltage corresponding to a nominal operating voltage of the high voltage battery unit. 3. The propulsion system according to claim 1 , wherein the non-faulty three-phase system is configured to provide vehicle propulsion and/or regenerative braking. 4. The propulsion system according to claim 1 , comprising a first power inverter connected to a first set of three phases of a dual winding three-phase electric machine and a second power inverter connected to a second set of three phases of the dual winding three-phase electric machine, wherein the first three-phase system is formed by the first power inverter and the first set of three phases of the dual winding three-phase electric machine and the second three-phase system is formed by the second power inverter and the second set of three phases of the dual winding three-phase electric machine. 5. The propulsion system according to claim 1 , comprising a six-phase power inverter connected to a six-phase electric machine, wherein the first three-phase system is formed by a first set of three phases of the six-phase power inverter and a corresponding first set of three phases of the six-phase electric machine and the second three-phase system is formed by a second set of three phases of the six-phase power inverter and a corresponding second set of three phases of the six-phase electric machine. 6. The propulsion system according to claim 1 , comprising a first three-phase power inverter connected to a first set of three phases of a six-phase electric machine and a second three-phase power inverter connected to a second set of three phases of the six-phase electric machine, wherein the first three-phase system is formed by a first three-phase power inverter and of a first set of three phases of the six-phase electric machine and the second three-phase system is formed by a second three-phase power inverter and a second set of three phases of the six-phase electric machine. 7. The propulsion system according to claim 1 , comprising a multilevel power inverter connected to an electric machine, wherein the propulsion system control unit is configured to detect a fault in a level of the multilevel power inverter and to control a non-faulty level of the multilevel inverter to provide vehicle propulsion and/or regenerative braking. 8. The propulsion system according to claim 1 , comprising an electric machine having three windings coupled to a three-phase AC charging inlet, wherein the propulsion system control unit is configured to charge the first and/or the second high voltage battery via the non-faulty three-phase system of the first and the second three-phase systems. 9. A vehicle comprising a propulsion system according to claim 1 . 10. A method for controlling a propulsion system for an electric vehicle having a high voltage battery unit having a first high voltage battery connected in series with a second high voltage battery such that a nominal operating voltage of the high voltage battery unit is the sum of a voltage of the first high voltage battery and a voltage of the second high voltage battery and one or more power inverters arranged to connect the high voltage battery unit and the first high voltage battery to one or more electric machines, wherein the one or more power inverters and the one or more electric machines are configured to form a first and a second three-phase system; the method comprising: detecting, by a propulsion system control unit, a fault in the first or the second three-phase system; if a back electromotive force, back-EMF, of the faulty three-phase system is lower than the operating voltage of the high voltage battery unit, operating the power inverter of the three-phase system comprising the phase where the fault was detected in a safe pulse-off mode by controlling the transistors of the power inverter of the three-phase system comprising the phase where the fault was detected to be in an open state and stopping switching of the transistors; and controlling the non-faulty three-phase system of the first and second three-phase system to provide field weakening current control to reduce the magnetic field in the faulty three-phase system. 11. The method according to claim 10 , further comprising controlling the power inverter of the non-faulty three-phase system to operate at a voltage higher than a nominal operating voltage of the non-faulty three-phase system during a transition period. 12. The method according to claim 10 , further comprising controlling the non-faulty three-phase system to provide vehicle propulsion and/or regenerative braking. 13. The method according to claim 10 , in a system having an electric machine having three windings coupled to a three-phase AC charging inlet, further comprising controlling the non-faulty three-phase system to charge the first and/or the second high voltage battery.