Method and control system for handling a reclosing operation in a power system

The invention claimed is: 1. A method of handling a reclosing operation of a recloser in a power system subject to a fault, wherein the method comprises: a) determining a fault current for each electrical phase, the fault current being determined by a difference between measured current values and a sinusoidal model of a current prior to the fault, bI) calculating a respective sinusoidal model of the fault current for each electrical phase using samples taken before the fault, bII) selecting two sinusoidal models with the largest amplitude to represent faulted electrical phases, bIII) calculating a plurality of sub-features based on the two models, wherein a first sub-feature is calculated based on a difference between the amplitudes of the two models, wherein a second sub-feature is calculated based on an average of a difference between, for each of the two sinusoidal models of the fault current, a number of samples of the sinusoidal model fault current and the fault current, wherein a third sub-feature is calculated based on a difference between 180° and the difference between the phases of the two sinusoidal models of the fault current, and bIV) determining a main feature value based on the plurality of sub-features, wherein the main feature value is a product of the sub-features, bV) determining, based on the main feature value, whether a temporary fault is present, and c) providing control instructions that the recloser is to reclose, and reclosing the recloser, in the event that it has been determined that the fault is a temporary fault. 2. The method as claimed in claim 1 , wherein a main feature value below a predefined value indicates that the fault is not a temporary fault of phase to phase type, and wherein a main feature value above the predefined value indicates that the fault is a temporary fault of phase to phase type. 3. The method as claimed in claim 1 , comprising determining a faulted electrical phase based on the magnitude of the fault currents determined in step a). 4. The method as claimed in claim 3 , comprising: bVI) determining conductance values of the faulted electrical phase based on the fault current and a corresponding voltage, and bVII) determining arcing current values based on the conductance values, bVIII) determining a plurality of instantaneous conductance values based on a ratio between the arcing current and the corresponding voltage, bIX) determining a first predetermined time range mean conductance value for each half-cycle in a first predetermined time range before the fault based on the instantaneous conductance values and a second predetermined time range mean conductance value for each half-cycle in a second predetermined time range before the fault, based on the instantaneous conductance values, wherein the second predetermined time range is closer to the fault than the first predetermined time range, and bX) determining whether a conductance increase has occurred based on a difference between an average of the first predetermined time range mean conductance values and a maximum of the second predetermined time range mean conductance values. 5. The method as claimed in claim 4 , wherein step bVI) involves setting the conductance value of a sample position to zero when the corresponding voltage is smaller than the absolute value of a rising portion threshold value in a rising portion of the voltage signal or smaller than the absolute value of a decreasing portion threshold value in a decreasing portion of the voltage signal. 6. The method as claimed in claim 4 , wherein step bVIII) involves applying a linear transform to the arcing current values and to the corresponding voltage values in the ratio to determine the instantaneous conductance values. 7. The method as claimed in claim 4 , comprising: bXI) determining a phase difference between a final zero-crossing of a voltage before an increase above a threshold value of the fault current and the fault current at the threshold value, wherein a phase difference above a phase difference threshold value dependent of the conductance increase provides an indication that a temporary fault of phase to ground type has occurred and wherein a phase difference below the phase difference threshold value indicates that the fault is a permanent fault of phase to ground type. 8. The method as claimed in claim 7 , wherein step c) comprises determining that a temporary fault of phase to ground type has occurred in case a conductance increase has occurred and the phase difference is above the phase difference threshold value, or that a permanent fault of phase to ground type has occurred in case a conductance increase has occurred and the phase difference is below the phase difference threshold value. 9. A non-transitory computer readable medium comprising computer-executable components which when executed by a processor circuitry causes a control system to perform a method including: a) determining a fault current for each electrical phase, the fault current being determined by a difference between measured current values and a sinusoidal model of a current prior to the fault, bI) calculating a respective sinusoidal model of the fault current for each electrical phase using samples taken before the fault, bII) selecting two sinusoidal models with the largest amplitude to represent faulted electrical phases, bIII) calculating a plurality of sub-features based on the two models, wherein a first sub-feature is calculated based on a difference between the amplitudes of the two models, wherein a second sub-feature is calculated based on an average of a difference between, for each of the two sinusoidal models of the fault current, a number of samples of the sinusoidal model fault current and the fault current, wherein a third sub-feature is calculated based on a difference between 180° and the difference between the phases of the two sinusoidal models of the fault current, and bIV) determining a main feature value based on the plurality of sub-features, wherein the main feature value is a product of the sub-features, bV) determining, based on the main feature value, whether a temporary fault is present, and c) providing control instructions that the recloser is to reclose, and reclosing the recloser, in the event that it has been determined that the fault is a temporary fault. 10. A control system for handling reclosing operations of a recloser in a power system subject to a fault, wherein the control system comprises: processor circuitry, and a storage unit storing instructions that, when executed by the processor circuitry causes the control system to perform a method including: a) determining a fault current for each electrical phase, the fault current being determined by a difference between measured current values and a sinusoidal model of a current prior to the fault, bI) calculating a respective sinusoidal model of the fault current for each electrical phase using samples taken before the fault, bII) selecting two sinusoidal models with the largest amplitude to represent faulted electrical phases, bIII) calculating a plurality of sub-features based on the two models, wherein a first sub-feature is calculated based on a difference between the amplitudes of the two models, wherein a second sub-feature is calculated based on an average of a difference between, for each of the two sinusoidal models of the fault current, a number of samples of the sinusoidal model fault current and the fault current, wherein a third sub-feature is calculated based on a difference between 180° and the difference between the phases of the two sinusoidal models of the fault current, and bIV) determining a main feature value based on the plural