Air gap driving mechanism of a solid-state circuit breaker includes permanent magnet(s) for contact separation

What is claimed is: 1. A solid-state circuit breaker comprising: a breaker housing; and an air gap driving mechanism including: a pair of opposing contacts, a first permanent magnet to generate a static magnetic field, a coil actuator to generate a dynamic magnetic field, and wherein the first permanent magnet and the coil actuator are positioned relative to each other such that the dynamic magnetic field generated by the coil actuator can either enhance or cancel the static magnetic field of the first permanent magnet, and hence a combination of the static magnetic field from the first permanent magnet and the dynamic magnetic field from the coil actuator can either drive the pair of opposing contacts open or drive the pair of opposing contacts close. 2. The solid-state circuit breaker of claim 1 , wherein the coil actuator consists of a coil and a ferromagnetic core and is fixed in the breaker housing. 3. The solid-state circuit breaker of claim 2 , wherein the first permanent magnet is fixed to one end of the ferromagnetic core and a non-magnetic stop is attached to the other end. 4. The solid-state circuit breaker of claim 1 , further comprising: a contact arm that is pivotally mounted in the breaker housing such that on one end of the contact arm a second permanent magnet is pivotally mounted, wherein the second permanent magnet can be attracted by the first permanent magnet such that the second permanent magnet provides stronger interaction with the first permanent magnet. 5. The solid-state circuit breaker of claim 4 , wherein on the other end of the contact arm a contact of the pair of opposing contacts is mounted which can close and open with a stationary contact of the pair of opposing contacts to close and open a current path. 6. The solid-state circuit breaker of claim 5 , further comprising: a reset spring that acts on the contact arm in a manner that it always tries to push the pair of opposing contacts open for fail safe purpose. 7. The solid-state circuit breaker of claim 6 , further comprising: a contact force spring that is loaded behind the stationary contact of the pair of opposing contacts to provide a necessary contact force. 8. The solid-state circuit breaker of claim 7 , wherein in an OFF position the coil actuator is not energized so the pair of opposing contacts are held open by the reset spring. 9. The solid-state circuit breaker of claim 8 , wherein from the OFF position if it is decided to close the pair of opposing contacts, the coil actuator is energized with a current direction in such a way that a first magnetic field is generated such that a magnetic field strength of the first permanent magnet is enhanced so it can attract the second permanent magnet to overcome the reset spring and eventually to close the pair of opposing contacts. 10. The solid-state circuit breaker of claim 9 , wherein with the first and the second permanent magnets now in touch with each other a magnetic force between them is strong enough to overcome the reset spring and the contact force spring which can hold the pair of opposing contacts closed and the solid-state circuit breaker is then in an ON position. 11. The solid-state circuit breaker of claim 10 , wherein from the ON position if it is decided to open the pair of opposing contacts, an opposite direction current is provided to the coil to generate a second magnetic field that is opposite to the first magnetic field such that a coil magnetic field cancels a magnetic field of both the first and the second permanent magnets, and hence eliminate an attraction force between the two causing the reset spring to then open the pair of opposing contacts. 12. The solid-state circuit breaker of claim 11 , further comprising: a manual override to manually push the second permanent magnet away from the first permanent magnet in the ON position and hence to open the pair of opposing contacts in case of electronics failure. 13. The solid-state circuit breaker of claim 1 , further comprising: a lockout feature in that before the pair of opposing contacts are closed, a self-test can be run to check the condition of components and circuitry and the pair of opposing contacts can be closed through the coil actuator only after the self-test passes whereas in case of the self-test failure, a control unit of the solid-state circuit breaker does not send current to the coil actuator so the pair of opposing contacts do not close. 14. The solid-state circuit breaker of claim 1 , wherein the contact separation is put inside a vacuum condition. 15. The solid-state circuit breaker of claim 1 , wherein the air gap driving mechanism is placed in a vacuum tube as a whole. 16. A method of controlling contact separation in an air gap driving mechanism of a solid-state circuit breaker, the method comprising: providing a breaker housing; and providing an air gap driving mechanism including: a pair of opposing contacts, a first permanent magnet to generate a static magnetic field, a coil actuator to generate a dynamic magnetic field, and wherein the first permanent magnet and the coil actuator are positioned relative to each other such that the dynamic magnetic field generated by the coil actuator can either enhance or cancel the static magnetic field of the first permanent magnet, and hence a combination of the static magnetic field from the first permanent magnet and the dynamic magnetic field from the coil actuator can either drive the pair of opposing contacts open or drive the pair of opposing contacts close. 17. The method of claim 16 , wherein the coil actuator consists of a coil and a ferromagnetic core and is fixed in the breaker housing. 18. The method of claim 17 , wherein the first permanent magnet is fixed to one end of the ferromagnetic core and a non-magnetic stop is attached to the other end. 19. The method of claim 16 , further comprising: providing a contact arm that is pivotally mounted in the breaker housing such that on one end of the contact arm a second permanent magnet is pivotally mounted, wherein the second permanent magnet can be attracted by the first permanent magnet such that the second permanent magnet provides stronger interaction with the first permanent magnet. 20. The method of claim 19 , wherein on the other end of the contact arm a contact of the pair of opposing contacts is mounted which can close and open with a stationary contact of the pair of opposing contacts to close and open a current path.