A process of manufacturing a heat resistant and low carbon plate for a circuit breaker includes preparing a heat resistant and low carbon plate for a circuit breaker; coating the heat resistant and low carbon plate with organic material; coating the organic material with inorganic material; and heating and drying the heat resistant and low carbon plate. The process continuously grips each of heat resistant and low carbon plates conveyed on a conveyor with a coat application device being used for the coating steps. A circuit breaker having the heat resistant and low carbon plate is also provided.

A process of manufacturing a heat resistant and low carbon plate for a circuit breaker includes preparing a heat resistant and low carbon plate for a circuit breaker; coating the heat resistant and low carbon plate with organic material; coating the organic material with inorganic material; and heating and drying the heat resistant and low carbon plate. The process continuously grips each of heat resistant and low carbon plates conveyed on a conveyor with a coat application device being used for the coating steps. A circuit breaker having the heat resistant and low carbon plate is also provided.

An electronic circuit breaker may include a monitoring circuit configured to monitor and respond to a power supply and/or detection circuit failure within the electronic circuit breaker. In some embodiments, the monitoring circuit may monitor a DC current received from a detection circuit within the electronic circuit breaker. A response to a power supply and/or detection circuit failure may include interrupting current flow between an electrical power source and an electrical circuit protected by the electronic circuit breaker. Methods of monitoring and responding to a power supply and/or detection circuit failure within an electronic circuit breaker are also provided, as are other aspects.

An electronic circuit breaker may include a monitoring circuit configured to monitor and respond to a power supply and/or detection circuit failure within the electronic circuit breaker. In some embodiments, the monitoring circuit may monitor a DC current received from a detection circuit within the electronic circuit breaker. A response to a power supply and/or detection circuit failure may include interrupting current flow between an electrical power source and an electrical circuit protected by the electronic circuit breaker. Methods of monitoring and responding to a power supply and/or detection circuit failure within an electronic circuit breaker are also provided, as are other aspects.

The invention relates to a surge protection device with connection elements, an overvoltage protection device (SE1), two contact elements (K1, K2), a slide (AS), a connection plate (B) and a force accumulator (F). The two contact elements (K1, K2) and the overvoltage protection device (SE1) are encased with an electrically nonconducting material on the surface. The electrically nonconducting material leaves open a connection area (A) formed on the second contact element (K2). In a first state, the connection plate (B) is connected to the connection area (A). The slide (AS) is arranged such that it can slide on a surface of the electrically nonconducting material under the action of the force when the thermally softenable contact means softens in a second state, wherein the slide (AS) is displaced between the connection plate (B) and the connection area (A). The electrically nonconducting material is assigned a further function.

The invention relates to a surge protection device with connection elements, an overvoltage protection device (SE1), two contact elements (K1, K2), a slide (AS), a connection plate (B) and a force accumulator (F). The two contact elements (K1, K2) and the overvoltage protection device (SE1) are encased with an electrically nonconducting material on the surface. The electrically nonconducting material leaves open a connection area (A) formed on the second contact element (K2). In a first state, the connection plate (B) is connected to the connection area (A). The slide (AS) is arranged such that it can slide on a surface of the electrically nonconducting material under the action of the force when the thermally softenable contact means softens in a second state, wherein the slide (AS) is displaced between the connection plate (B) and the connection area (A). The electrically nonconducting material is assigned a further function.

A thermal fuse includes a casing wall configured to transfer heat energy generated exterior to the casing wall to a thermally activated device disposed in an interior of the casing wall. The thermally activated device is configured for activation at a preselected temperature. The casing wall includes a coating layer disposed on an adjacent layer. The coating layer forms an outermost surface of the casing wall and has an emissivity greater than the adjacent layer of the casing wall.

An engageable drive engageable operating mechanism for converting a movement of a linear translation operating handle to a rotating handle movement relative to the operative front face engageable with a molded-case circuit breaker. The mechanism includes an external rotating adapter external rotating operating member or alternatively an engageable drive engageable operating mechanism incorporating a handle assembly external rotating operating member, interchangeable with each other; and a gear, a support movable movement-converting support including a rack portion, and a structural support base, wherein the structural support base includes a built-in side opening chamber.

An engageable drive engageable operating mechanism for converting a movement of a linear translation operating handle to a rotating handle movement relative to the operative front face engageable with a molded-case circuit breaker. The mechanism includes an external rotating adapter external rotating operating member or alternatively an engageable drive engageable operating mechanism incorporating a handle assembly external rotating operating member, interchangeable with each other; and a gear, a support movable movement-converting support including a rack portion, and a structural support base, wherein the structural support base includes a built-in side opening chamber.

An electrical switching apparatus includes a housing member, a printed circuit board assembly having a board including a first side and a second side facing away from the first side, and a barrier member coupled to each of the housing member and the first side of the board. The barrier member substantially encapsulates the first side of the board.