Method in, apparatus for, and interface arrangement between an alternating current power system and a direct current power system

The invention claimed is: 1. An interface arrangement configured to couple an alternating current, AC, power system with a direct current, DC, power system, the interface arrangement lacking additional auxiliary equipment and comprising: at least one converter for conversion of AC power to DC power, wherein the at least one converter comprises a DC side for coupling of the converter to the DC power system and an AC side for coupling of the converter to the AC power system; a transformer comprising a primary side for coupling of the transformer to the AC power system and a secondary side for coupling of the transformer to the at least one converter; a multi-phase current path comprising a plurality of conductors for coupling the AC power system with the DC power system; a circuit breaker arranged in a current path between the transformer and the AC power system, the circuit breaker being configured to controllably effect discontinuation of flow of current in each of the plurality of conductors of the current path upon opening of contacts of the circuit breaker independently of the other ones of the plurality of conductors; a fault sensing unit configured to sense a fault occurring in the interface arrangement; and a control and processing module communicatively coupled to the fault sensing unit, wherein the control and processing module is configured to control operation of the circuit breaker at least with respect to opening of the circuit breaker, and wherein the control and processing module is configured to open the contacts of the circuit breaker if there is determined to be a fault occurring in the interface arrangement, and wherein the control and processing module is further configured to, if a fault in the interface arrangement as sensed by the fault sensing unit occurs in a current path in a predefined portion of the interface arrangement for a conductor of the plurality of conductors, delay opening of the contacts of the circuit breaker by a selected delay time period for the conductor for which a fault is sensed so as to effect discontinuation of flow of current in the conductor by a selected delay time period compared to if the fault would have been within a portion of the interface arrangement different from the predefined portion and without delay for the other conductors, and wherein the fault in the interface arrangement as sensed by the fault sensing unit is a phase to ground fault and the selected delay time period is between about 20 ms and 100 ms and the delay is implemented through the control and processing module being configured to send an instruction issued after the detection of the fault that is delayed by the selected delay time period and the predefined portion of the interface arrangement is a current path between the secondary side of the transformer and the AC side of the at least one converter. 2. A converter station configured to couple an alternating current power system with a direct current power system, the converter station comprising the interface arrangement according to claim 1 . 3. A power system including an alternating current, AC, power system and a direct current, DC, power system, the power system comprising the interface arrangement according to claim 1 configured to couple the AC power system with the DC power system. 4. The interface arrangement according to claim 1 , wherein the fault sensing unit comprises a current sensing unit configured to: sense a current at the DC side of the at least one converter and/or at the AC side of the at least one converter; and sense a current between the AC power system and the DC side of the at least one converter, at a different position than the sensing of current at the DC side of the at least one converter and/or at the AC side of the at least one converter. 5. The interface arrangement according to claim 4 , wherein the current sensing unit comprises: a first current sensor configured to sense a current at the DC side of the at least one converter and/or at the AC side of the at least one converter; and a second current sensor configured to sense a current at a different position than the first current sensor, between the AC power system and the DC side of the at least one converter. 6. The interface arrangement according to claim 5 , wherein the fault sensing unit is configured to determine a differential current based on the currents sensed by the current sensing unit, and based on the differential current, determine that there is a fault in the interface arrangement. 7. A converter station configured to couple an alternating current power system with a direct current power system, the converter station comprising the interface arrangement according to claim 5 . 8. A power system including an alternating current, AC, power system and a direct current, DC, power system, the power system comprising the interface arrangement according to claim 5 configured to couple the AC power system with the DC power system. 9. The interface arrangement according to claim 4 , wherein the fault sensing unit is configured to determine a differential current based on the currents sensed by the current sensing unit, and based on the differential current, determine that there is a fault in the interface arrangement. 10. The interface arrangement according to claim 9 , wherein the fault sensing unit is configured to determine that there is a fault in the interface arrangement on a condition that a magnitude of the differential current exceeds a predefined differential current threshold value for a predefined period of time. 11. A converter station configured to couple an alternating current power system with a direct current power system, the converter station comprising the interface arrangement according to claim 10 . 12. A power system including an alternating current, AC, power system and a direct current, DC, power system, the power system comprising the interface arrangement according to claim 10 configured to couple the AC power system with the DC power system. 13. A converter station configured to couple an alternating current power system with a direct current power system, the converter station comprising the interface arrangement according to claim 9 . 14. A power system including an alternating current, AC, power system and a direct current, DC, power system, the power system comprising the interface arrangement according to claim 9 configured to couple the AC power system with the DC power system. 15. A power system including an alternating current, AC, power system and a direct current, DC, power system, the power system comprising the interface arrangement according to claim 4 configured to couple the AC power system with the DC power system. 16. A converter station configured to couple an alternating current power system with a direct current power system, the converter station comprising the interface arrangement according to claim 4 . 17. A computer program product configured to be executed in a control and processing module of an interface arrangement configured to couple an alternating current, AC, power system with a direct current, DC, power system, or vice versa, the interface arrangement lacking additional auxiliary equipment and comprising: at least one converter for conversion of AC power to DC power, wherein the at least one converter comprises a DC side for coupling of the converter to the DC power system and an AC side for coupling of the converter to the AC power system; a transformer comprising a primary side for coupling of the transformer to the AC power system and a se