A button assembly is disclosed including a plastic cover having an upper body portion and a lower flange portion, the upper body portion having a top wall and an interior cavity, wherein a port is formed in the top wall of the upper body portion and the lower flange portion is adapted and configured to be welded to a wall of a plastic housing, and an elastomeric button over-molded on the plastic cover and including an upper actuation portion and a lower body portion, wherein the upper actuation portion extends through the port formed in the top wall of the upper body portion of the cover, and the lower body portion resides in the interior cavity of the upper body portion of the cover.

A button assembly is disclosed including a plastic cover having an upper body portion and a lower flange portion, the upper body portion having a top wall and an interior cavity, wherein a port is formed in the top wall of the upper body portion and the lower flange portion is adapted and configured to be welded to a wall of a plastic housing, and an elastomeric button over-molded on the plastic cover and including an upper actuation portion and a lower body portion, wherein the upper actuation portion extends through the port formed in the top wall of the upper body portion of the cover, and the lower body portion resides in the interior cavity of the upper body portion of the cover.

A sealing assembly for prevention of ingress of particulates and water into an electrical switch includes an engagement element with a rigid first abutment portion for circumscribing an aperture extending through the outer surface of the switch housing and a rigid first retention portion. Also included is a sealing element being slidingly engageable with the engagement element that includes a first complementary abutment portion. The sealing element is formed from an elastically resilient polymeric material so that sealing engagement with the engagement element occludes passage and ingress of external particulates, dust and water.

A vacuum interrupter includes: one movable contact fixed on a movable contact stem; and one fixed contact with a fixed contact stem. The fixed contact and the movable contact are located in a electrically insulating tube, which is vacuumtightly closed by metal lids at boths sides. The fixed contact stem is placed vacuumtightly on one of the metal lids, and the movable contact stem is guided trough an opening of the opposite metal lid via an axially extendable vacuumtight bellow. In order to create a twist protection of the movable contact stem, a ring disc shaped plastic part with a central opening, through which the movable contact stem is guided, is connected externally to the vacuum interrupter such that inner spanner flats inside the opening complementarily fit closely to external spanner flats of the movable contact stem.

A sealing assembly for prevention of ingress of particulates and water into an electrical switch includes an engagement element with a rigid first abutment portion for circumscribing an aperture extending through the outer surface of the switch housing and a rigid first retention portion. Also included is a sealing element being slidingly engageable with the engagement element that includes a first complementary abutment portion. The sealing element is formed from an elastically resilient polymeric material so that sealing engagement with the engagement element occludes passage and ingress of external particulates, dust and water.

An autoclavable handle (5) includes a handle housing (9) and with at least one switch element (11) mounted to the handle housing (9). The autoclavable handle (5) is permanently resistant to the effects of machine cleaning and of steam sterilization. The at least one switch element (11) is resiliently pressable into the handle housing (9). The switch element (11) is mounted in the handle housing (9) via at least one web (16) arranged on an underside of the switch element (11). The switch element (11) is sealed off from the handle housing (9) via a circumferential sealing element (12).

A vacuum interrupter is provided for use in a low voltage residential circuit breaker. The vacuum interrupter comprises a sealed vacuum tube. The sealed vacuum tube is being closed at a first end with an end plate and closed at a second end with an end spring. The vacuum interrupter comprises a first contact terminal passing through the end plate and having a fixed contact near a distal end of the first contact terminal. The vacuum interrupter comprises a second contact terminal having a free end. The second contact terminal passing through the end spring and having a movable contact being configured to contact the fixed contact of the first contact terminal. The end spring is configured to receive a force on the free end of the second contact terminal to provide open or close operations of the vacuum interrupter.

A manual disconnect switching device includes an external housing having a handle actuator. The manual disconnect switching device further includes a bellows actuator in communication with the handle actuator and hermetically sealed within an internal volume of the external housing. The bellows actuator includes a shaft and a biased bellows for switching the manual disconnect switching device between open and closed positions.

A switch includes a pushbutton comprising an actuating portion, a first fixed contact element and a first movable contact element facing the first fixed contact element for establishing a first switching way. The first movable contact element may include a movable portion of a first elastically deformable conductive blade. The actuating portion may include a first cam which cooperates with a cam follower portion of the first blade to deform or relax the first blade for longitudinally moving the first movable contact element to come into contact, or out of contact, with the portion of the first fixed contact element, depending on the vertical position of the actuation member. A second fixed contact element and second movable contact may be similarly constructed to provide a second switching way.

Apparatus and associated methods relate to a housing having a deformable membrane configured to interface with a programming module of an industrial product, where the deformable membrane includes a waved surface designed to deform under the finger pressure of a human user. In an illustrative example, the housing may be formed of a rigid material (e.g., polyamide) to serve as a protective barrier for the industrial product. The waved surface may have one or more waves (e.g., 7) that may possess certain dimensions and deformation parameters that are designed to allow a user to engage a programming switch via the deformable membrane. A user may advantageously provide input to the programming module via the deformable membrane without having to access the internal areas of the industrial product, thus avoiding the risk of damaging or interfering with the internal mechanisms and systems of the industrial product.