Circuit breakers with polarity sensitive shunt trip mechanisms and methods of operating the same

That which is claimed: 1. A circuit breaker comprising: at least one set of breaker contacts; a contact actuating mechanism configured to open and close the at least one set of breaker contacts; and a polarity sensitive shunt trip mechanism mechanically coupled to the contact actuating mechanism and configured to lock the contact actuating mechanism responsive to a shunt trip voltage of a first polarity to prevent closing of the at least one set of breaker contacts and to unlock the contact actuating mechanism responsive to a shunt trip voltage of a second polarity to enable closing of the at least one set of breaker contacts, wherein the second polarity is opposite the first polarity. 2. The circuit breaker of claim 1 , wherein the shunt trip mechanism comprises: an actuator member configured to engage the contact actuating mechanism; an electromagnet configured to receive the shunt trip voltages and to move the actuator member responsive thereto; and a locking device configured to impede movement of the actuator member. 3. A circuit breaker comprising: at least one set of breaker contacts; a contact actuating mechanism configured to open and close the at least one set of breaker contacts; and a polarity sensitive shunt trip mechanism mechanically coupled to the contact actuating mechanism and configured to lock the contact actuating mechanism responsive to a shunt trip voltage of a first polarity to prevent closing of the at least one set of breaker contacts and to unlock the contact actuating mechanism responsive to a shunt trip voltage of a second polarity to enable closing of the at least one set of breaker contacts, wherein the shunt trip mechanism comprises: an actuator member configured to engage the contact actuating mechanism; an electromagnet configured to receive the shunt trip voltages and to move the actuator member responsive thereto; and a locking device configured to impede movement of the actuator member, wherein the locking device is configured to be magnetically actuated by the electromagnet. 4. The circuit breaker of claim 2 : wherein the actuator member comprises an arm having an end that engages a moveable member of the contact actuating mechanism; wherein the electromagnet is configured to attract the arm to pivot the arm about a pivot point to move the moveable member from a first position to a second position; and wherein the locking device is configured to constrain the arm to maintain the moveable member in the second position. 5. The circuit breaker of claim 4 , wherein the locking device is configured to be magnetically actuated by the electromagnet. 6. The circuit breaker of claim 4 : wherein the shunt trip mechanism further comprises a shaft; wherein the electromagnet comprises a coil disposed proximate a first end of the shaft; wherein the arm comprises a plate having a first portion on a first side of a pivot point configured to engage the moveable member and a second portion on a second side of the pivot point and having an opening therein through which the shaft passes such that the opening moves along the shaft as the plate pivots; and wherein the locking device is configured to impede movement of the second portion of the plate with respect to the shaft. 7. The circuit breaker of claim 6 , wherein the locking device comprises a latch configured to engage the second portion of the plate. 8. The circuit breaker of claim 7 , wherein the latch comprises: a flexible member disposed along the shaft and having a toothed portion extending therefrom in a direction perpendicular to an axis of the shaft; and a magnetic slide disposed on the shaft and configured to be drawn along the shaft towards the coil responsive to the shunt trip voltage of the first polarity to thereby displace the toothed portion of the flexible member away from the shaft and thereby engage the second portion of the plate with the toothed portion and to be forced away from the coil along the shaft responsive to the shunt trip voltage of the second polarity to release the flexible member and disengage the toothed portion from the second portion of the plate. 9. A shunt trip mechanism comprising: an actuator member configured to engage a contact actuating mechanism; an electromagnet configured to move the actuator member from a first position to a second position responsive to a shunt trip voltage of a first polarity; and a locking device configured to lock the actuator member in the second position and to enable movement of the actuator member from the second position to the first position responsive to a shunt trip voltage of a second polarity that is opposite the first polarity. 10. The shunt trip mechanism of claim 9 , wherein the locking device is configured to be magnetically actuated by the electromagnet. 11. A shunt trip mechanism comprising: an actuator member configured to engage a contact actuating mechanism; an electromagnet configured to move the actuator member from a first position to a second position responsive to a shunt trip voltage of a first polarity; and a locking device configured to lock the actuator member in the second position and to enable movement of the actuator member from the second position to the first position responsive to a shunt trip voltage of a second polarity, wherein the actuator member comprises an arm having an end that engages a moveable member of the contact actuating mechanism; wherein the electromagnet is configured to attract the arm to pivot the arm about a pivot point and thereby move the moveable member from a first position to a second position; and wherein the locking device is configured to constrain the arm to maintain the moveable member in the second position. 12. The shunt trip mechanism of claim 11 , further comprising a shaft, wherein the electromagnet comprises a coil disposed proximate a first end of the shaft, wherein the arm comprises a plate having a first portion on a first side of a pivot point configured to engage the moveable member and a second portion on a second side of the pivot point and having an opening therein through which the shaft passes such that the opening moves along the shaft as the plate pivots, and wherein the locking device is configured to impede movement of the second portion of the plate with respect to the shaft. 13. The shunt trip mechanism of claim 12 , wherein the locking device comprises a latch configured to engage the second portion of the plate. 14. The shunt trip mechanism of claim 13 , wherein the latch comprises: a flexible member disposed along the shaft and having a toothed portion extending therefrom in a direction perpendicular to an axis of the shaft; and a magnetic slide disposed on the shaft and configured to be drawn along the shaft towards the coil responsive to the shunt trip voltage of the first polarity to displace the toothed portion of the flexible member away from the shaft and thereby engage the second portion of the plate with the toothed portion and to be forced away from the coil along the shaft responsive to the shunt trip voltage of the second polarity to release the flexible member and disengage the toothed portion from the second portion of the plate. 15. A method of operating a circuit breaker, the method comprising: applying a shunt trip voltage of a first polarity to a shunt trip mechanism to actuate a contact actuating mechanism; locking the contact actuating mechanism using the shunt trip mechanism to prevent closing of at least one set of contacts controlled by the contact actuating mechanism; and releasing the contact actuating mechanism by appl