A button assembly for an exterior of a vehicle is disclosed. The button assembly is designed with improved water drainage properties. The button assembly includes a button switch and a bezel housing surrounding the button switch that is spaced apart from the button switch. A channel extends between the two components. In one example, the channel has a width of approximately 0.5 mm at one end. In another example, the channel is formed between two surfaces, and the outer surface is sloped relative to the button switch by approximately 15 degrees. Furthermore, in some examples, the channel has a height of approximately 3 mm. Each of these structural characteristics serves to significantly improve the assembly's overall drainage performance, which may be especially essential in colder climates.

An electrical device such as, for example, an electrical switch is disclosed. The switch being arranged and configured to prevent ingress or intrusion of water, dust, or the like from the external environment thus making the switch particularly suitable for use outdoors or indoors where water and dust are expected. In one embodiment, the switch includes a base or housing, an internal actuator positioned within an internal cavity of the base, an external actuator accessible by a user, a barrier layer positioned between the internal actuator and the external actuator, the barrier layer arranged and configured to seal the internal cavity and the internal actuator, and a magnetic coupling arranged and configured to transfer movement of the external actuator to the internal actuator through the barrier layer.

An electrical device such as, for example, an electrical switch is disclosed. The switch being arranged and configured to prevent ingress or intrusion of water, dust, or the like from the external environment thus making the switch particularly suitable for use outdoors or indoors where water and dust are expected. In one embodiment, the switch includes a base or housing, an internal actuator positioned within an internal cavity of the base, an external actuator accessible by a user, a barrier layer positioned between the internal actuator and the external actuator, the barrier layer arranged and configured to seal the internal cavity and the internal actuator, and a magnetic coupling arranged and configured to transfer movement of the external actuator to the internal actuator through the barrier layer.

An enclosure adapter for a circuit breaker that converts a panel mounted circuit breaker to a flat surface mounted circuit breaker. The enclosure adapter has a housing with a top end, an open bottom end, and sides defining an interior. The open bottom end allows for insertion of a circuit breaker into the interior. The top end has an opening to provide access to controls on the circuit breaker and has openings for attaching the circuit breaker to an interior side of the top end. Mounting members are formed at the bottom end of the enclosure adapter to mount the enclosure adapter to a flat surface. The sides form corners which are indentations into the interior of the enclosure adapter and the mounting members are formed in the indentations, wherein the indentations facilitate mounting the enclosure adapter to a flat surface. Removable tabs create openings for electrical connections.

An enclosure adapter for a circuit breaker that converts a panel mounted circuit breaker to a flat surface mounted circuit breaker. The enclosure adapter has a housing with a top end, an open bottom end, and sides defining an interior. The open bottom end allows for insertion of a circuit breaker into the interior. The top end has an opening to provide access to controls on the circuit breaker and has openings for attaching the circuit breaker to an interior side of the top end. Mounting members are formed at the bottom end of the enclosure adapter to mount the enclosure adapter to a flat surface. The sides form corners which are indentations into the interior of the enclosure adapter and the mounting members are formed in the indentations, wherein the indentations facilitate mounting the enclosure adapter to a flat surface. Removable tabs create openings for electrical connections.

A rotation operation detection mechanism that includes a housing, an operation surface disposed on a first main surface of the housing, operation units formed integrally with the housing and protruding on the operation surface side, and a sensor that detects a stress generated in the housing when the operation units are rotated.

In one aspect, the application provides an electrical system including a conductor, a ground, an arrester electrically connected to the conductor, and a disconnector assembly electrically connected between the arrester and the ground. The disconnector assembly includes an isolator configured to perform an operating function in response to the occurrence of an event and a housing configured to surround the isolator. The isolator includes a first terminal electrically connected to the arrester by a first wire and a second terminal electrically connected to the ground by a second wire. The housing includes a first opening through which the first terminal extends, a second opening through which the second terminal extends, and a retention mechanism configured to hold the isolator in place relative to the arrester.

This auxiliary contact unit includes a case and a case that are divided from each other in the width direction. The case includes a side wall portion and a partition wall portion protruding from a wall surface of the side wall portion toward the case. The case includes a side wall portion having a wall surface with which a tip end of the partition wall portion comes into contact when the case is assembled to the case. A space surrounded by the side wall portion, the partition wall portion, and the side wall portion serves as a contact housing portion. The side wall portion includes a pass-by wall portion protruding from a wall surface toward the side wall portion along the partition wall portion.

A switch device includes a panel housing a knob, the panel having a wall face around the knob. In at least one of outside faces of the knob, the outside faces opposing the wall face and another member adjacent to the knob, the outside face has a base part formed on an upper side thereof and a recess part formed in a lower side thereof. The recess part extends to a lower end of the outside face. The base part has an obliquely downwardly inclined parts formed on a lower edge part thereof. Accordingly, the device can ensure stable operation of the knob by discharging, from a gap between the panel and the knob, liquid that has entered the gap.

The present disclosure is directed to a for manufacturing a switching apparatus for electric systems. The method includes (i) providing a first housing shell of the switching apparatus; (ii) providing a second housing shell of the switching apparatus; (iii) assembling the first and second housing shells and a number of operating components of the switching apparatus, thereby obtaining a preliminary assembly of the switching apparatus; and (iv) joining first and second coupling edges of the first and second housing shells through a vibration welding process, thereby forming a junction between the first and second housing shells and obtaining a sealed outer casing for the switching apparatus.