A hinged busbar assembly includes a first mounting busbar configured to be electrically and mechanically connected to the first component at a fixed connection, a second mounting busbar configured to be electrically and mechanically connected to the second component at a fixed connection, and at least two extension busbars extending between the first and second mounting busbars. Adjacent extension busbars are electrically and mechanically connected to each other at a pivotal connection. One of the at least two extension busbars is electrically and mechanically connected to the first mounting busbar at a pivotal connection, and another one of the at least two extension busbars is electrically and mechanically connected to the second mounting busbar at a pivotal connection. Each pivotal connection includes at least one extension extending from each adjacent busbar and at least one electrical contact mounted in each extension, and a pin inserted through the electrical contacts.

A switching and/or distributing device has at least one receiving housing and a housing cover. Arranged in at least one housing rail region are one or a plurality of power distribution rails which extend substantially in a main plane and arc connected to sub-distribution rails. In at least a first plane, said sub-distribution rails extend substantially in parallel to the main plane and arc electrically insulated from one another and extend in the direction of at least one housing component region, wherein in the housing component region, in particular modular components, which contain electrical/electronic operating means, arc in electrical contact with one sub-distribution rail each. As a result, a switching and/or distributing device is improved in such a way that the arrangement of corresponding components is possible easily without much additional effort even in potentially explosive atmospheres and a plurality of components of different ty pes and of different sizes can be arranged at the same time.

A hinged busbar assembly includes a first mounting busbar configured to be electrically and mechanically connected to the first component at a fixed connection, a second mounting busbar configured to be electrically and mechanically connected to the second component at a fixed connection, and at least two extension busbars extending between the first and second mounting busbars. Adjacent extension busbars are electrically and mechanically connected to each other at a pivotal connection. One of the at least two extension busbars is electrically and mechanically connected to the first mounting busbar at a pivotal connection, and another one of the at least two extension busbars is electrically and mechanically connected to the second mounting busbar at a pivotal connection. Each pivotal connection includes at least one extension extending from each adjacent busbar and at least one electrical contact mounted in each extension, and a pin inserted through the electrical contacts.

A hybrid busbar (1) for a busbar system, said hybrid busbar (1) comprising a current carrying rail profile (2) adapted to carry an electrical current with a predefined high current amplitude and at least one contact receiving rail profile (3) having a plurality of equally spaced contact openings (4) configured to receive protruding electrical contacts (6) of electrical devices (ED-A) to be connected to said busbar system, wherein the current carrying rail profile (2) and the contact receiving rail profile (3) are connected with each other to form said hybrid busbar (1) providing at least one bounding geometry with a rectangular cross section (CS), wherein the hybrid busbar (1) can be engaged from behind by hook-shaped mounting latches (7) of electrical devices (ED-B) to be connected to said busbar system.

A hybrid busbar (1) for a busbar system, said hybrid busbar (1) comprising a current carrying rail profile (2) adapted to carry an electrical current with a predefined high current amplitude and at least one contact receiving rail profile (3) having a plurality of equally spaced contact openings (4) configured to receive protruding electrical contacts (6) of electrical devices (ED-A) to be connected to said busbar system, wherein the current carrying rail profile (2) and the contact receiving rail profile (3) are connected with each other to form said hybrid busbar (1) providing at least one bounding geometry with a rectangular cross section (CS), wherein the hybrid busbar (1) can be engaged from behind by hook-shaped mounting latches (7) of electrical devices (ED-B) to be connected to said busbar system.

A busbar power supply apparatus comprising at a rear side of its housing an AC interface with electrical contacts configured to establish an electrical connection with AC busbars of a busbar system to receive AC mains voltages converted by an integrated AC/DC power conversion unit into a DC power supply voltage applied to at least one DC interface of said busbar power supply apparatus.

A power meter socket assembly includes a primary meter stack section with a first bus section including conductors oriented in a first plane and an extension meter stack section including a second bus section including conductors oriented in the first plane. The assembly includes a first connection section including flexible conductors. Each flexible conductor includes a first end electrically connected to a conductor of the first bus section and a second end electrically connected to a conductor of the second bus section. The assembly includes a power bus connection section and a disconnect switch. The switch includes line terminals electrically connected to the bus connection section and load terminals connected to the first bus section. The assembly includes a second connection section including flexible conductors oriented parallel to and below the first bus section to connect the line terminals of the switch to the bus connection section.

A power meter socket assembly includes a primary meter stack section with a first bus section including conductors oriented in a first plane and an extension meter stack section including a second bus section including conductors oriented in the first plane. The assembly includes a first connection section including flexible conductors. Each flexible conductor includes a first end electrically connected to a conductor of the first bus section and a second end electrically connected to a conductor of the second bus section. The assembly includes a power bus connection section and a disconnect switch. The switch includes line terminals electrically connected to the bus connection section and load terminals connected to the first bus section. The assembly includes a second connection section including flexible conductors oriented parallel to and below the first bus section to connect the line terminals of the switch to the bus connection section.

The present invention relates to a switching device arrangement, comprising a plurality of switching devices, which are mounted in common on a mounting profiled rail, in particular a top hat rail, wherein the switching devices are connected to a bus system comprising at least one data bus and/or energy bus for transferring control signals and/or for supplying energy, wherein the bus system is integrated at least partially into the mounting profiled rail and the switching devices have bus connections for connecting to the bus system in the mounting profiled rail.

A multi-phase busbar for conducting electric energy includes: a base layer of an insulating material; a first conducting layer of a sheet metal; a first insulating layer of an insulating material arranged on the first conducting layer; a second conducting layer of a sheet metal arranged on the insulating layer; and a second layer of an electrically insulating material which is arranged on the second conducting layer. The first and/or second insulating layers include spacers, each spacer including a layer of a rigid insulating material. At least one of the spacers is glued to an electrically insulating coating of the first and/or second conducting layer, and/or at least one of the spacers is glued to an electrically conductive surface of an uncoated first and/or second conducting layer by an adhesive.