Trip free relay

The invention claimed is: 1. An overload relay, comprising: an electromagnetic activation path comprising single coil and an armature that, in operation, moves movable contacts between set and tripped states with respect to stationary contacts, a magnet to hold the armature in the set state, and wherein for tripping, the coil produces a coil magnetic flux to overcome a magnet magnetic flux of the magnet to release the armature to the tripped state under the influence of a spring; and a mechanical activation path comprising a manually operated reset member that causes the armature to move between the tripped and set states; wherein the electromagnetic activation path and the mechanical activation path can both move the armature between the set and tripped states without selection of a tripping mode of operation; and wherein when the coil is energized to produce the coil magnetic flux to overcome magnet magnetic flux of the magnet, manual operation of the reset member will not cause resetting of the armature to the set state; wherein the same stationary contacts may be wired for normally open or normally closed operation, and wherein the mechanical activation path comprises a lever and a pin connected to the lever, the lever being moved by the reset member, and the pin extending through the coil to contact the armature upon manual actuation of the reset member. 2. The overload relay of claim 1 , wherein the mechanical activation path comprises a trip prevention spring having characteristics that prevent the reset member overcoming the coil when the coil is energized. 3. The overload relay of claim 2 , wherein the spring is disposed in the mechanical activation path between the reset member and a lever that urges tripping of the armature. 4. The overload relay of claim 1 , comprising circuitry for pulse width modulating power to energize the coil at least to trip the relay. 5. The overload relay of claim 4 , wherein the circuitry comprises a first path through an h-bridge for energizing the coil from tripping, and a second path through the h-bridge for energizing the coil for setting. 6. The overload relay of claim 5 , wherein each of the h-bridge paths comprises a capacitor to permit tripping and setting in case of loss of input power. 7. The overload relay of claim 1 , comprising control circuitry coupled to the coil to control energization of the coil, and wherein the control circuitry is configured to de-energize the coil after movement of the armature from the trip state to the set state, and from the set state to the trip state. 8. An overload relay, comprising: an armature that, in operation, moves movable contacts between set and tripped states with respect to stationary contacts; a magnet that in operation produces a magnet magnetic flux to hold the armature in the set state; a single coil energizable in a first manner to attract the armature to the set state, and in a second manner to produce a coil magnetic flux to overcome the magnet magnetic flux to overcome the magnet magnetic flux to release the armature to the tripped state under the influence of a spring; and a mechanical activation path comprising a manually operated reset member that causes the armature to move between the tripped and set states; wherein the armature is bistable in the set and tripped states; and wherein the electromagnetic activation path and the mechanical activation path can both move the armature between the set and tripped states; and wherein when the coil is energized to produce the coil magnetic flux to overcome the magnet magnetic flux of the magnet, manual operation of the reset member will not cause resetting of the armature to the set state; and wherein the same stationary contacts may be wired for normally open or normally closed operation; wherein the mechanical activation path comprises a lever and a pin connected to the lever, the lever being moved by the reset member, and the pin extending through the coil to contact the armature upon manual actuation of the reset member. 9. The relay of claim 8 , comprising a spring to maintain the armature in a tripped state. 10. The overload relay of claim 8 , wherein the mechanical activation path comprises a trip prevention spring having characteristics that prevent the reset member overcoming the coil when the coil is energized. 11. The overload relay of claim 10 , wherein the spring is disposed in the mechanical activation path between the reset member and the lever. 12. The overload relay of claim 8 , comprising control circuitry coupled to the coil to control energization of the coil, and wherein the control circuitry is configured to de-energize the coil after movement of the armature from the trip state to the set state. 13. The overload relay of claim 12 , wherein the control circuitry is configured to de-energize the coil after movement of the armature from the set state to the trip state. 14. An overload relay, comprising: an electromagnetic activation path comprising a single coil and an armature that, in operation, moves movable contacts between set and tripped states with respect to stationary contacts, a magnet to hold the armature in the set state, and wherein for tripping, the coil produces a coil magnetic flux to overcome a magnet magnetic flux of the magnet to release the armature to the tripped state under the influence of a spring; and a mechanical activation path comprising a manually operated reset member that causes the armature to move between the tripped and set states; wherein the armature is bistable in the set and tripped states, and wherein the electromagnetic activation path and the mechanical activation path can both move the armature between the set and tripped states while in the same physical configuration and without selection of a tripping mode of operation; and wherein the same stationary contacts may be wired for normally open or normally closed operation, and wherein the mechanical activation path comprises a lever and a pin connected to the lever, the lever being moved by the reset member, and the pin extending through the coil to contact the armature upon manual actuation of the reset member. 15. The overload relay of claim 14 , wherein when the coil is energized to overcome the magnet, manual operation of the reset member will not cause resetting of the armature to the set state. 16. The overload relay of claim 15 , wherein the mechanical activation path comprises a trip prevention spring having characteristics that prevent the reset member overcoming the coil when the coil is energized. 17. The overload relay of claim 16 , wherein the spring is disposed in the mechanical activation path between the reset member and the lever. 18. The overload relay of claim 14 , comprising control circuitry coupled to the coil to control energization of the coil, and wherein the control circuitry is configured to de-energize the coil after movement of the armature from the trip state to the set state. 19. The overload relay of claim 18 , wherein the control circuitry is configured to pulse width modulate energization of the coil to ensure that the magnet is overcome by the coil for electromagnetically tripping the relay.