A switching device arrangement has a first contact set and a second contact set. The first contact set includes a first electric arc contact element and a first nominal current contact element. The first nominal current contact element can be moved relative to the first electric arc contact element. A first transmission is introduced in a kinematic chain in order to generate a relative movement of the first nominal current contact element and the first electric arc contact element. The first transmission is operationally connected between a stationary counter bearing and the first electric arc contact piece.

A switchgear system operable at voltages up to 27 kV includes an enclosure containing atmospheric air and a loadbreak module disposed within the enclosure. The loadbreak module includes a loadbreak module housing made of a solid dielectric material, a vacuum interrupter enclosed within the loadbreak module housing and having a fixed contact and a movable contact, and an interchange electrically connected to the movable contact. The vacuum interrupter is operable to selectively break or establish an electrical pathway between the interchange and a terminal in response to movement of the movable contact relative to the fixed contact. The switchgear system further includes a bushing coupled to the enclosure and a disconnect switch electrically connected in series between the loadbreak module and the bushing. The disconnect switch includes a disconnect switch housing made of a solid dielectric material.

A fixation system in use for medium or high voltage switching poles, insulators, circuit breakers, or general devices includes: an insulating housing provided with holes, in which screws are screwed into, in order to fix the device on a support, or a further housing. Inner surfaces of the holes are covered with a conductive layer or layers covering the inner surfaces at least partly. The conductive layers extend toward outside the holes. The conductive layers are conductively connected or connectable to ground potential.

An electromechanical actuator includes an electrically insulating rod, an electrically insulating cover at least partly encompassing the electrically insulating rod, and an elastomeric diaphragm. The electrically insulating rod has a body, a first actuation portion connected to an electromechanical drive mechanism arranged in a first region, and a second actuation portion for actuating an electromechanical actuation mechanism arranged in a second region. The elastomeric diaphragm unit is arranged between the body and the cover. The elastomeric diaphragm unit has a flexible membrane electrically separating the first region from the second region. The elastomeric diaphragm unit is coated on at least one surface of the membrane with a semiconductive layer.

An electromechanical actuator includes an electrically insulating rod, an electrically insulating cover at least partly encompassing the electrically insulating rod, and an elastomeric diaphragm. The electrically insulating rod has a body, a first actuation portion connected to an electromechanical drive mechanism arranged in a first region, and a second actuation portion for actuating an electromechanical actuation mechanism arranged in a second region. The elastomeric diaphragm unit is arranged between the body and the cover. The elastomeric diaphragm unit has a flexible membrane electrically separating the first region from the second region. The elastomeric diaphragm unit is coated on at least one surface of the membrane with a semiconductive layer.

An electromechanical actuator includes an electrically insulating rod, an electrically insulating cover at least partly encompassing the electrically insulating rod, and an elastomeric diaphragm. The electrically insulating rod has a body, a first actuation portion connected to an electromechanical drive mechanism arranged in a first region, and a second actuation portion for actuating an electromechanical actuation mechanism arranged in a second region. The elastomeric diaphragm unit is arranged between the body and the cover. The elastomeric diaphragm unit has a flexible membrane electrically separating the first region from the second region. The elastomeric diaphragm unit is coated on at least one surface of the membrane with a semiconductive layer.

An electromechanical actuator includes an electrically insulating rod, an electrically insulating cover at least partly encompassing the electrically insulating rod, and an elastomeric diaphragm. The electrically insulating rod has a body, a first actuation portion connected to an electromechanical drive mechanism arranged in a first region, and a second actuation portion for actuating an electromechanical actuation mechanism arranged in a second region. The elastomeric diaphragm unit is arranged between the body and the cover. The elastomeric diaphragm unit has a flexible membrane electrically separating the first region from the second region. The elastomeric diaphragm unit is coated on at least one surface of the membrane with a semiconductive layer.

A fixation system in use for medium or high voltage switching poles, insulators, circuit breakers, or general devices includes: an insulating housing provided with holes, in which screws are screwed into, in order to fix the device on a support, or a further housing. Inner surfaces of the holes are covered with a conductive layer or layers covering the inner surfaces at least partly. The conductive layers extend toward outside the holes. The conductive layers are conductively connected or connectable to ground potential.

A high voltage electric power switch with an anti-flashover nozzle that suppresses the likelihood of a flashover occurring between switch components other than the switch contactors, such as the nozzle casing around the first contactor (e.g., female or socket) and the casing around the second contactor (e.g., male or pin) during an opening stroke of the contactors. The anti-flashover features include a corona ring positioned at the proximal end of the nozzle casing and a nozzle clamp ring positioned to the distal side of a nozzle casing abutment that mates with a nozzle receiver. The conventional nozzle includes a nib-shaped proximal end of the nozzle casing carrying a clamp ring positioned on the proximal side of the abutment. The new nozzle design reduces the high level of electric field stress created by the conventional nozzle casing to suppress the likelihood of a flashover occurring between the contactor casings.

A high voltage electric power switch with an anti-flashover nozzle that suppresses the likelihood of a flashover occurring between switch components other than the switch contactors, such as the nozzle casing around the first contactor (e.g., female or socket) and the casing around the second contactor (e.g., male or pin) during an opening stroke of the contactors. The anti-flashover features include a corona ring positioned at the proximal end of the nozzle casing and a nozzle clamp ring positioned to the distal side of a nozzle casing abutment that mates with a nozzle receiver. The conventional nozzle includes a nib-shaped proximal end of the nozzle casing carrying a clamp ring positioned on the proximal side of the abutment. The new nozzle design reduces the high level of electric field stress created by the conventional nozzle casing to suppress the likelihood of a flashover occurring between the contactor casings.