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.

An elongated busbar board for connection of devices to a power busbar system comprises a front side touch protection cover plate consisting of touch protection cover plate segments made of an electrically insulating material and having feedthrough openings The touch protection cover plate is adapted to cover power busbars made of an electrically conductive material having contact openings lying directly beneath the feedthrough openings and comprises a touch protection base plate connected to the touch protection cover plate and consisting of touch protection base plate segments made of the electrically insulating material and adapted to cover the power busbars enclosed by the elongated busbar board from behind. 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 for connection of devices to a power busbar system comprises a front side touch protection cover plate consisting of touch protection cover plate segments made of an electrically insulating material and having feedthrough openings The touch protection cover plate is adapted to cover power busbars made of an electrically conductive material having contact openings lying directly beneath the feedthrough openings and comprises a touch protection base plate connected to the touch protection cover plate and consisting of touch protection base plate segments made of the electrically insulating material and adapted to cover the power busbars enclosed by the elongated busbar board from behind. A thermal expansion difference caused by different thermal expansion coefficients of the electrically insulating material and of the electrically conductive material is compensated.

Embodiments of the present disclosure relate to a busway and a corresponding electrical component. The busway includes a profile and a conductor. The profile is disposed on a first side, a second side and a third side, wherein the first side and the second side are parallel to each other, the third side is parallel to an extending direction of the busway and adjacent to the first side and the second side, and at least a part of the profile on the first side and the second side is planar. The conductor is disposed within a space defined by the first side, the second side and the third side, and the conductor is U-shaped and opens towards a fourth side that is parallel to the third side and adjacent to the first side and the second side. According to embodiments of the present disclosure, a fast, reliable electrical connection can be achieved.

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.

A ridge vent may cover a ridge slot in a roof of the structure to provide ventilation. A housing having a length, a width and a height that are sized to fit through a ridge slot of the roof includes a top a top portion proximal to the ridge vent, a bottom portion proximal to the interior of the structure and opposite to the top portion, and at least one wall extending between the top portion and the bottom portion. A securing mechanism is connected to the top portion of the housing to secure the housing within the ridge slot. An electronics bus is positioned within the housing and has an interface that enables operation of modular electronic devices that are removably positioned within the housing.

A ridge vent may cover a ridge slot in a roof of the structure to provide ventilation. A housing having a length, a width and a height that are sized to fit through a ridge slot of the roof includes a top a top portion proximal to the ridge vent, a bottom portion proximal to the interior of the structure and opposite to the top portion, and at least one wall extending between the top portion and the bottom portion. A securing mechanism is connected to the top portion of the housing to secure the housing within the ridge slot. An electronics bus is positioned within the housing and has an interface that enables operation of modular electronic devices that are removably positioned within the housing.

A rigid bus duct comprising a pair of side rails extending in a longitudinal direction, a plurality of support members extending between the side rails in a transverse direction, and a plurality of insulated conductors extending longitudinally, and held in a fixed relationship to one another by the plurality of support members. The plurality of insulated conductors are arranged in groups including a plurality of high current phase groups and a neutral group, and a plurality of shielding structures connected between the support members and positioned with at least one shielding structure located between the insulated conductors of each high current phase group.

A track busway power distribution unit including a housing, a power input coupled with the housing and connectable to an electrical busway, a securement mechanism moveably coupled to the housing and structured to secure the power distribution unit to the electrical busway, and at least one outlet module located at least partially within the housing. The outlet module can include at least one outlet core having a core outer surface configured to mate within a first connector type. The outlet core can include a plurality of electrical terminals each coupled to the power input and configured to connect with mating terminals corresponding to both the first connector type and a second connector type that is different than the first connector type. A removable shroud can be positioned around the outlet core, wherein the shroud includes a shroud inner surface configured to receive the first connector type.