Contractor assembly which counteracts electromagnetic repulsion of contacts

The invention claimed is: 1. A contactor assembly adapted for switching power to a circuit having a power source, the contactor assembly comprising: a housing; current carrying contacts disposed in the housing, the current carrying contacts including conductive bodies that protrude from the housing; a coupling member, the coupling member having conductive pads for engaging the current carrying contacts, a contact bridge extends from a first curved section of the coupling member to a second curved section of the coupling member, mating members extend from ends of the curved sections which are not in contact with the contact bridge, the conductive pads are mounted on the mating members, the mating members are spaced from the contact bridge, the conductive pads extend in a direction toward the current carrying contacts and away from the contact bridge section; an actuator assembly which moves the coupling member between a closed position in which the conductive pads of the coupling member engage the current carrying contacts and an open position in which the conductive pads of the coupling member are disengaged from the current carrying contacts; opposing electromagnetic forces generated between the contact bridge and the conductive pads to resist electromagnetic repulsion forces generated between the current carrying contacts and the conductive pads when the actuator assembly is in the closed position. 2. The contactor assembly of claim 1 , wherein the conductive pads are formed from a conductive material which is softer than a conductive material of the contact bridge. 3. The contactor assembly of claim 1 , wherein the mating members and curved sections form C-shaped members at either end of the contact bridge. 4. The contactor assembly of claim 1 , wherein the housing includes an interior compartment with internal walls which laterally extend within the interior compartment to define a protection chamber, the coupling member is disposed in the protection chamber of the housing. 5. The contactor assembly of claim 4 , wherein the current carrying contacts are disposed in the protection chamber of the housing, the current carrying contacts including conductive bodies that protrude from the housing and are configured to close the circuit. 6. A switch assembly adapted for switching power to a circuit having a power source, the switch assembly comprising: current carrying contacts; a coupling member, the coupling member having conductive pads for engaging the current carrying contacts, a contact bridge extends from a first curved section of the coupling member to a second curved section of the coupling member, mating members extend from ends of the curved sections which are not in contact with the contact bridge, the conductive pads are mounted on the mating members, the mating members are spaced from the contact bridge, the conductive pads extend in a direction toward the current carrying contacts and away from the contact bridge section; an actuator assembly which moves the coupling member between a closed position in which the conductive pads of the coupling member engage the current carrying contacts and an open position in which the conductive pads of the coupling member are disengaged from the current carrying contacts; opposing electromagnetic forces generated between the contact bridge and the conductive pads to resist electromagnetic repulsion forces generated between the current carrying contacts and the conductive pads as the actuator assembly approaches or is in the closed position. 7. The switch assembly of claim 6 , wherein the mating members and curved sections form C-shaped members at either end of the contact bridge. 8. The switch assembly of claim 7 , wherein the conductive pads are formed from a conductive material which is softer than a conductive material of the contact bridge. 9. A method of activating a switch assembly adapted for switching power to a circuit having a power source, the method comprising: moving a coupling member from an open position to a closed position, the coupling member having conductive pads for engaging stationary current carrying contacts of the switch assembly, a contact bridge extends from a first curved section of the coupling member to a second curved section of the coupling member, mating members extend from ends of the curved sections which are not in contact with the contact bridge, the conductive pads are mounted on the mating members, the mating members are spaced from the contact bridge, the conductive pads extend in a direction toward the current carrying contacts and away from the contact bridge section; electrically coupling the contact pads of the coupling member to the current carrying contacts as the coupling member approaches the closed position; creating electromagnetic repulsion forces between the contact pads and the current carrying contacts; creating opposing electromagnetic forces which act upon the conductive pads to oppose the electromagnetic repulsion forces; wherein as the opposing electromagnetic force counteracts the electromagnetic repulsion force, the opposing electromagnetic force prevents or eliminates the bouncing of the conductive pads from the current carrying contacts during the mating of the conductive pad with the current carrying contacts, allowing the mating to be more easily predicted and controlled. 10. The method as recited in claim 9 , further comprising eliminating or reducing arcing across the conductive pads and the current carrying contact. 11. The method as recited in claim 9 , further comprising directing current flow through the conductive pads in an opposite direction as current flow through a contact bridge of the coupling member which connects the contact pads, wherein the opposite flow of current creates the opposing electromagnetic forces which act upon the conductive pads to oppose the electromagnetic repulsion forces. 12. The method as recited in claim 9 , further comprising increasing the opposing electromagnetic force to counteract transient pulse current or other current is applied across the current carrying contacts and the conductive pads when the coupling member is in the closed position during operation, wherein unwanted movement of the conductive pads and the coupling member is prevented. 13. The method as recited in claim 11 , wherein the conductive pads are formed from a conductive material which is softer than a conductive material of the contact bridge.