Alternating current switch contactor

The invention claimed is: 1. An electrical contactor comprising: a first terminal having a fixed member with at least one fixed electrical contact; a second terminal; at least one electrically-conductive movable arm in electrical communication with the second terminal and having a movable electrical contact thereon; and an AC dual-coil actuator having a first drive coil drivable to open and close the movable and fixed electrical contacts, and a second non-drive coil feedback directly connected to an AC±common center of the AC dual-coil actuator to induce a reverse flux to temper and stabilise a nett flux, thereby enabling control of a delay time of the opening and closing electrical contacts so as to be at or adjacent to a zero-crossing of an associated AC load current. 2. The electrical contactor of claim 1 , wherein the driving of the first drive coil induces a reverse flux through feedback connection in the second non-drive coil to temper and stabilise a nett flux, thereby controlling a delay time of the opening and closing of the first and second electrical contacts. 3. The electrical contactor of claim 1 , wherein the AC dual-coil actuator is a magnet-latching solenoid actuator, the magnet-latching solenoid actuator including a plunger. 4. The electrical contactor of claim 3 , wherein the magnet-latching solenoid is reverse drivable. 5. The electrical contactor of claim 4 , comprising at least one biasing spring for biasing the plunger to a contacts closed position. 6. The electrical contactor of claim 1 , further comprising a driving circuit in electrical communication with at least the first drive coil of the AC dual-coil actuator. 7. The electrical contactor of claim 6 , wherein the driving circuit supplies a drive pulse to the first drive coil having a half-cycle waveform profile. 8. The electrical contactor of claim 6 , wherein the driving circuit supplies a drive pulse to the first drive coil having a quarter-cycle waveform profile. 9. A two-pole electrical contactor comprising: two feed terminals and two outlet terminals, each outlet terminal being connected to a pair of contacts on opposite faces of an electrically-conductive first member; two pairs of moveable arms, one pair of moveable arms being clamped at one end to one feed terminal, and the other pair of moveable arms being clamped at one end to the other terminal, each arm carrying a moveable contact at a distal end of the arm from the feed terminal, the moveable arms being arranged such that the distal ends are on either side of the respective first member; a reverse-drivable magnet-latching solenoid having a first drive coil drivable to open and close the movable and fixed electrical contacts, and a second non-drive coil feedback directly connected to an AC± common center of the AC dual-coil actuator to induce a reverse flux to temper and stabilise a nett flux, thereby enabling control of a delay time of the opening and closing electrical contacts so as to be at or adjacent to a zero-crossing of an associated AC load current; and at least one moveable member associated with a plunger of the reverse-drivable magnet-latching solenoid, for providing an actuation each pair of moveable arms. 10. The electrical contactor of claim 9 , wherein there is further provided a driving circuit in electrical communication with at least the first drive coil of the AC dual-coil actuator. 11. The electrical contactor of claim 10 , wherein the driving circuit supplies a drive pulse to the first drive coil having a half-cycle waveform profile. 12. The electrical contactor of claim 10 , wherein the driving circuit supplies a drive pulse to the first drive coil having a quarter-cycle waveform profile. 13. A method of controlling electrical contact closing and opening delay, the method comprising the steps of driving a first coil of an AC dual-coil actuator to open and close electrical contacts of an electrical contactor, and inducing a reverse flux through feedback connection in a second coil which is feedback directly connected to an AC± common center of the AC dual-coil actuator to temper and stabilise a nett flux in the actuator, thereby controlling a delay time of the opening and closing electrical contacts. 14. The method of claim 13 , wherein the first coil of the AC dual-coil actuator is energised with half-cycle waveform drive pulses to reduce or limit erosion energy applied between contacts. 15. The method of claim 14 , wherein the first coil of the AC dual-coil actuator is energised with quarter-cycle waveform drive pulses to prevent contact separation prior to peak load current. 16. A method of limiting or preventing electrical contact bounce and arc duration, the method comprising the steps of driving a first coil of an AC dual-coil actuator to open and close electrical contacts of an electrical contactor, and inducing a reverse flux through feedback connection in a second coil which is feedback directly connected to an AC± common center of the AC dual-coil actuator to temper and stabilise a nett flux in the actuator, thereby controlling a delay time of the opening and closing electrical contacts so as to be at or adjacent to a zero-crossing of an associated AC load current. 17. The method of claim 16 , wherein the first coil of the AC dual-coil actuator is energised with half-cycle waveform drive pulses to reduce or limit erosion energy applied between contacts. 18. The method of claim 16 , wherein the first coil of the AC dual-coil actuator is energised with quarter-cycle waveform drive pulses to prevent contact separation prior to peak load current. 19. A method of limiting or preventing electrical contact bounce and arc duration, the method comprising the step of driving an electrical actuator to open and close electrical contacts of an electrical contactor, a drive pulse being applied to drive the electrical actuator having a truncated-waveform. 20. The method of claim 19 , wherein the truncated-waveform is based on a peak load current.