A barrier includes a cover and an attachment apparatus and is usable with an electrical interruption device. The attachment apparatus includes a number of attachment structures that are situated on the cover and that are each structured to be engaged with at least one of the housing of the electrical interruption device and a number of terminal assemblies of the electrical interruption device. The cover is configured to overlie at least a portion of the electrical interruption device and to resist the entry of a probe of known dimensions into electrical contact with components that are electrified even when the electrical interruption device is in an OFF condition.

The present disclosure relates to finger-safe requirements for breaker modules from electrical panel boards and envisages a finger safe cover 100a for a terminal of an electrical switching device 50. The finger safe cover comprises a cover body 110a with an expandable aperture section 120a. The aperture section 120a has an annulus 122a having a primary aperture 124a and a coupling section 126a surrounding the annulus 122a. The primary aperture 124a allows a thinner conducting cable 52 to pass therethrough. The coupling section 126a couples the annulus 122a with the cover body 110a. The aperture section 120a defines a secondary aperture 128a when the annulus 122a is detached from the cover body 110a by breaking the coupling section 126a, to allow to pass therethrough a thicker conducting cable 54. The cover 100a passes the IPXXB test, eliminates the need of safety accessories and is easy to install.

A terminal shield for a circuit breaker, formed of an electrically insulating material, protects an operator from inadvertently touching the load terminal that would otherwise be exposed on the bottom side of the circuit breaker: In accordance with an example embodiment of the invention, the terminal shield is integrated with a toroidally shaped current transformer sensor, to enable measuring the current in a load wire that has been inserted through an aperture in the terminal shield. Preferably there is an access hole in the front portion of the terminal shield, which allows the operator to insert a tool through the front face of the circuit breaker, to tighten the load terminal onto the load wire. The terminal shield with the integrated current transformer sensor enables standardization of load current sensing capability for circuit breakers and further enables ease of installation without clutter in the confined regions of the load center.

Hazardous location compliant solid state circuit protection devices include safety lockout components ensuring disconnection as a safeguard in the completion of power system maintenance and service tasks by responsible personnel. The safety lockout components may include a mechanical lockout interfacing with a physical lock element, an electrical lockout implemented through the controls of the solid state circuit breaker device, and combinations thereof. Visual device feedback and confirmation may be provided to personnel that the lockouts have been successfully activated, as well as successfully deactivated to reconnect and restore operation of the load side circuitry.

The present invention implements, through a simple structure, the prevention of an electric shock caused by contacting an output terminal in a conducting state. This electric shock protection structure is provided with: a protective cover (40) which changes an output terminal into a non-conducting state by pressing a power switch (51) during the transition of the output terminal from a covered state to an exposed state; and a housing cover (60) which cannot be moved when the output terminal is in the non-conducting state by having an L-shaped curved section (60A), which is positioned on a different surface from the surface on which the output terminal is disposed, does not contact a contact section (44A) of the protective cover (40) when the protective cover (40) exposes the output terminal, and contacts the contact section (44A) when the protective cover (40) covers the output terminal.

A coupler between an activator mounted on an enclosure and an electronic protection device located within the enclosure facilitates alignment between the coupler and the electronic protection device during installation and requires no tool for installation. The coupler is positioned over an opening in the electronic protection device and oriented such that a first coupling portion is configured to engage a complementary coupling portion on the electronic protection device. The coupler may be manually mounted, engaging the complementary coupling portions on the door handle coupler and the electronic protection device without requiring a tool for installation. The coupler includes an upper sleeve configured to receive an axle, also connected to the activator, that rotates independently of a lower sleeve which is mounted to the electronic protection device, facilitating orientation of the activator on the outside of the enclosure. The coupler also provides for local lock-out of the electronic protection device.

Solid state and hybrid circuit protection devices include improved arc-less switching capability and overcurrent protection, improved terminal assemblies and improved thermal management features that reduce or eliminate ignition sources for hazardous environments. The solid state and hybrid circuit protection devices are ignition protected and avoid possible explosions and therefore obviate a need for conventional explosion-proof enclosures to ensure safe operation of an electrical power system in a hazardous location.

The present disclosure relates to a circuit breaker having a main circuit unit cover and, more particularly, to a circuit breaker having a removable main circuit unit cover so as to be applicable to a change in rated capacity. A circuit breaker according to one embodiment of the present disclosure comprises: a main circuit unit connected to a power source and a load; a main circuit unit cover which insulatively covers the rear surface of the main circuit unit; a main circuit unit terminal connected to the main circuit unit and exposed to the outside through the main circuit unit cover; and a terminal protection member detachably coupled to the main circuit unit cover and insulatively covering the main circuit unit terminal.

Compliant electrical circuit protection devices are described for use in hazardous environments without presenting ignition risks for potentially explosive environmental conditions. Sensing features and systems may evaluate wiring limits and user selected settings for compatibility, detect loose connections and operating parameters to ensure safe operation of the device, and to intelligently diagnose and manage issues of concern for the circuit protection devices as well as the larger electrical power system.

A protection structure is disclosed and is applied in a fuse link switch. The fuse link switch comprises: an insulator, a fuse tube including an upper connection portion and a lower connection portion, an upper-end fixing unit, a lower-end fixing unit, and a toggle mechanism, wherein the upper connection portion is connected with a pull hook. The protection structure comprises at least one electrically insulating shielding layer covering at least one of the upper-end fixing unit, the pull hook, the upper connection portion, the lower connection portion, the lower-end fixing unit, and the toggle mechanism through overmolding technique.