A filter component includes a housing body. A first and at least one second busbar each have a first end section, and a second end section, between which in each case a center section is arranged. The end sections of the busbars each have connections for connecting electrical conductors to the filter component. The first and second end section and the center section of the first busbar are arranged in a first plane and the first and second end section and the center section of the at least one second busbar are arranged in a second plane, which is different from the first plane.

A device for the electrification of furniture includes at least a first furniture panel, which has, in one of its two panel sides, two parallel grooves and two exposed busbars laid respectively in the two grooves and at least one electric plug for connecting to the two busbars. The plug has two electrical contacts, which are formed as exposed collector contacts on a connecting side of the plug housing and as connection contacts on a front side of the plug housing. The plug is inserted into a bore, interrupting the two grooves, in the one panel side of the first furniture panel. The collector contacts each lie against the two busbars in an electrically conductive manner.

A device for the electrification of furniture includes at least a first furniture panel, which has, in one of its two panel sides, two parallel grooves and two exposed busbars laid respectively in the two grooves and at least one electric plug for connecting to the two busbars. The plug has two electrical contacts, which are formed as exposed collector contacts on a connecting side of the plug housing and as connection contacts on a front side of the plug housing. The plug is inserted into a bore, interrupting the two grooves, in the one panel side of the first furniture panel. The collector contacts each lie against the two busbars in an electrically conductive manner.

An elongated busbar board (1) for connection of devices (11) to a power busbar system comprises a front side touch protection cover plate (2) consisting of touch protection cover plate segments (2-i) made of an electrically insulating material and having feedthrough openings (7) for electrical connection contacts (13A) of devices (11) to be connected to the elongated busbar board. The touch protection cover plate is adapted to cover power busbars (6) made of an electrically conductive material having contact openings (5) lying directly beneath the feedthrough openings and comprises a touch protection base plate (3) connected to the touch protection cover plate and consisting of touch protection base plate segments (3-i) made of the electrically insulating material and adapted to cover the power busbars enclosed by the elongated busbar board from behind, wherein a thermal expansion difference caused by different thermal expansion coefficients of the electrically insulating material and of the electrically conductive material is compensated.

An elongated busbar board (1) for connection of devices (11) to a power busbar system comprises a front side touch protection cover plate (2) consisting of touch protection cover plate segments (2-i) made of an electrically insulating material and having feedthrough openings (7) for electrical connection contacts (13A) of devices (11) to be connected to the elongated busbar board. The touch protection cover plate is adapted to cover power busbars (6) made of an electrically conductive material having contact openings (5) lying directly beneath the feedthrough openings and comprises a touch protection base plate (3) connected to the touch protection cover plate and consisting of touch protection base plate segments (3-i) made of the electrically insulating material and adapted to cover the power busbars enclosed by the elongated busbar board from behind, wherein a thermal expansion difference caused by different thermal expansion coefficients of the electrically insulating material and of the electrically conductive material is compensated.

A switchgear assembly includes a plurality of gas insulated switches arranged in at least one row and a plurality of enclosures arranged in at least one row forming at least one channel extending parallel to the at least one row of switches. The switchgear assembly further includes at least one bus assembly disposed in the at least one channel and including a plurality of interconnected bus sections having an insulating covering and electrically connected to the gas insulated switches.

A switchgear assembly includes a plurality of gas insulated switches arranged in at least one row and a plurality of enclosures arranged in at least one row forming at least one channel extending parallel to the at least one row of switches. The switchgear assembly further includes at least one bus assembly disposed in the at least one channel and including a plurality of interconnected bus sections having an insulating covering and electrically connected to the gas insulated switches.

A server chassis includes a baseboard, a power distribution board, and a busbar module. The baseboard includes a front end and a rear end. The front end and the rear end define a chassis depth. The power distribution board is positioned on the baseboard. The busbar module includes a chassis-side busbar connector. The chassis-side busbar connector is configured to mate with a rack-side busbar connector. The rack-side busbar connector is positioned on a rack having a rack depth. The busbar module is adjustable, such that the chassis-side busbar connector mates with the rack-side busbar connector in a first configuration and a second configuration. In the first configuration, the rack depth is approximately equal to the chassis depth. In the second configuration, the rack depth is greater than the chassis depth.

A server chassis includes a baseboard, a power distribution board, and a busbar module. The baseboard includes a front end and a rear end. The front end and the rear end define a chassis depth. The power distribution board is positioned on the baseboard. The busbar module includes a chassis-side busbar connector. The chassis-side busbar connector is configured to mate with a rack-side busbar connector. The rack-side busbar connector is positioned on a rack having a rack depth. The busbar module is adjustable, such that the chassis-side busbar connector mates with the rack-side busbar connector in a first configuration and a second configuration. In the first configuration, the rack depth is approximately equal to the chassis depth. In the second configuration, the rack depth is greater than the chassis depth.

Disclosed are a DC terminal multi-stage filter structure, a motor controller and a vehicle. The DC terminal multi-stage filter structure is fixed on a controller enclosure. A head end of a DC terminal is provided with a high voltage bus and a tail end of the DC terminal is provided with a film capacitor. The DC terminal multi-stage filter structure includes a primary filter holder assembly and a secondary filter holder assembly. The primary filter holder assembly and the secondary filter holder assembly are provided inside the controller enclosure in a line along a length direction of the controller enclosure.