A circuit breaker includes a first electrical contact and a second electrical contact moveable between an open state and a closed state; an armature, wherein movement of the armature from a first position to a second position initiates the first electrical contact and the second electrical contact to move from the closed state to the open state; a first electromagnetic device configured to move the armature from the first position to the second position in response to being energized by a first signal; and a second electromagnetic device configured to move the armature from the first position to the second position in response to being energized by a second signal and in response to generation of the first signal and the first electrical contact and the second electrical contact still being in the closed state. Other circuit breakers and methods of operating circuit breakers are disclosed.

A circuit breaker includes a short-circuit trip and an overcurrent trip. The short-circuit trip has a trip coil, and the overcurrent trip has a bimetallic element. A first terminal of the trip coil is conductively connected to a fixed contact carrier of the circuit breaker. The bimetallic element is connected in series with the trip coil. The bimetallic element is connected at least indirectly to a first connection terminal of the circuit breaker, and the first connection terminal is connected to the fixed contact carrier by a bypass line.

A magnetic module in a circuit interrupting system is configured to generate a blow-on force that pushes a moving contact toward a stationary contact. The magnetic module includes: a coil conductor having an opening through which a moving stem of the moving contact may move, wherein the coil conductor is electrically connected to the moving stem and a first auxiliary conductor, wherein the coil conductor is configured to allow current to flow from the moving stem to the first auxiliary conductor; a plunger attached to an end of the moving stem; and a first magnetic core shaped to fit around a first section of the coil conductor, wherein the first magnetic core is configured, when current flows through the coil conductor to the first auxiliary conductor, to become magnetized, attract the plunger toward the magnetic core, and cause the moving stem of the moving contact to move toward the stationary contact.

A smart residential circuit breaker includes a hybrid assembly that incorporates a solid-state circuit element integrated into a simplified mechanical pole having main contacts. The solid-state circuit element includes a printed circuit board (PCB) with a micro SD reader to provide faster opening speeds. The smart residential circuit breaker is configured for use for different current levels and controlled by the PCB. The smart residential circuit breaker includes a mag-latch. The PCB is configured to send a signal to the mag-latch to open and close the main contacts within microseconds of detecting an over-current.

A multi-pole circuit breaker such as a residential electronic circuit breaker is provided. It includes a means to prevent a breaker mechanism from latching, i.e., a breaker armature from latching with a cradle if certain criterion is met. In particular, the multi-pole circuit breaker comprises a breaker mechanism including a breaker armature, a cradle and an armature latch bar to prevent the breaker armature from latching with the cradle. The armature latch bar includes a recessed feature that interfaces with the breaker armature, an armature latching surface that needs to be removed before the breaker mechanism can be latched and an armature latching lever that prevents a rotation of the breaker armature.

A magnetic module in a circuit interrupting system is configured to generate a blow-on force that pushes a moving contact toward a stationary contact. The magnetic module includes: a coil conductor having an opening through which a moving stem of the moving contact may move, wherein the coil conductor is electrically connected to the moving stem and a first auxiliary conductor, wherein the coil conductor is configured to allow current to flow from the moving stem to the first auxiliary conductor; a plunger attached to an end of the moving stem; and a first magnetic core shaped to fit around a first section of the coil conductor, wherein the first magnetic core is configured, when current flows through the coil conductor to the first auxiliary conductor, to become magnetized, attract the plunger toward the magnetic core, and cause the moving stem of the moving contact to move toward the stationary contact.

A circuit breaker includes a first electrical contact and a second electrical contact moveable between an open state and a closed state; an armature, wherein movement of the armature from a first position to a second position initiates the first electrical contact and the second electrical contact to move from the closed state to the open state; a first electromagnetic device configured to move the armature from the first position to the second position in response to being energized by a first signal; and a second electromagnetic device configured to move the armature from the first position to the second position in response to being energized by a second signal and in response to generation of the first signal and the first electrical contact and the second electrical contact still being in the closed state. Other circuit breakers and methods of operating circuit breakers are disclosed.

A power circuit breaker has a housing defining a first passage and a cross passage through the housing. A bus bar extends through the cross passage and is configured to transmit electric power and/or break transmission of the electric power through the housing. The bus bar includes at least an input section, a coin or center section, and an output section that are separable from each other. The housing aligns a solenoid piston within the first passage of the housing. The solenoid has a piston with two opposite ends, and one of the ends operates as a plunger to separate the sections of the bus bar when the solenoid is actuated. The plunger moves the coin or center section of the bus bar out of contact with the input section and the output section of the bus bar to break electrical transmission across the bus bar.

An electromagnetic trip unit, wherein: the electromagnetic trip unit includes a movable core, an upper static core and a lower static core; the movable core can move relative to the upper static core and the lower static core in the upper static core and the lower static core; a movable core body end of a movable core body of the movable core faces and approaches the lower static core end of the lower static core, when the electromagnetic trip unit is not released, a first magnetic field air gap is formed between the movable core body end and the lower static core end; the movable core body of the movable core is also provided with a movable core body step, when the electromagnetic trip unit is not released, a second magnetic field air gap is formed between the movable core body step and the lower static core end.

A trip assembly is for an electrical switching apparatus. The electrical switching apparatus has a base, a pair of separable contacts, and a trip bar structured to cooperate with the separable contacts in order to trip open the separable contacts. The trip assembly includes a housing member structured to be coupled to the base, and an lockout assembly having an actuation member and a locking member each coupled to the housing member. The actuation member is configured to engage the trip bar in order to trip open the separable contacts. The lockout assembly is structured to move between a FIRST position corresponding to the separable contacts being closed, and a SECOND position corresponding to the separable contacts being open. When the lockout assembly is in the SECOND position, the locking member engages the actuation member in order to maintain the separable contacts in the open position.