An example busway system is provided that includes a first busway, a second busway, and a joint seal coupling the first busway to the second busway. The first busway includes a first end and an opposing second end, and the second busway includes a third end and an opposing fourth end. The joint seal includes panels configured to at least partially slide over the first or the opposing second end of the first busway, and at least partially slide over the third or the opposing fourth end of the second busway to couple the first busway to the second busway. The joint seal creates a seal at a joint formed by the first busway, the second busway, and the joint seal.

An electrical grounding system can include an electrically conductive column configured for communication with a fault current source, wherein the electrically conductive column can include an open-ended copper tube, and carbon fiber fabric assembled onto at least a portion of the electrically conductive column, the carbon fiber fabric having a conductive relationship with at least a portion of the electrically conductive column.

An electrical grounding system can include an electrically conductive column configured for communication with a fault current source, wherein the electrically conductive column can include an open-ended copper tube, and carbon fiber fabric assembled onto at least a portion of the electrically conductive column, the carbon fiber fabric having a conductive relationship with at least a portion of the electrically conductive column.

A sensor device contains a busbar, a dielectric shell arranged over the busbar, a dielectric layer arranged over the busbar, and a sensor chip arranged within the dielectric shell, wherein the sensor chip is configured to detect a magnetic field induced by an electric current flowing through the busbar.

A phase module assembly includes a first flat laminated busbar elongated along a first direction, including a positive layer, a negative layer, and a load layer that is configured to be conductively coupled with a load. The first flat laminated busbar is conductively coupled to a second flat laminated busbar extending in a plane that is orthogonal to the first direction. The second flat laminated busbar is conductively coupled with a power source of direct current. The phase module assembly also includes one or more switches conductively coupled with internal terminal connectors of the first flat laminated busbar and configured to convert the direct current into one phase of a multi-phase alternating current, and to output the phase to the load. The phase module assembly also includes one or more capacitors mechanically mounted on and conductively coupled with the second flat laminated busbar.

A bus bar system having at least one bus bar which is accommodated in a contact-protection housing in a contact-protection manner and in an accessible manner via contacting passages for electrical devices and/or device adapters, the contact-protection housing having a lower part and an upper part which is detachably fixed on the lower part and between which the at least one bus bar is held, wherein the upper part has, on its side facing the lower part, a plurality of plug-in receptacles extending from the latter into the lower part, and the lower part has at least one slide with at least one latching pawl which can be adjusted between a locking position, in which the at least one latching pawl engages in the plug-in receptacle, and a release position, in which the at least one latching pawl is positioned in front of the plug-in receptacle. A corresponding method is further described.

A stack-type busbar includes one or more flexible flat cables (FFCs), each having at least one opening where the busbar is bent.

A stack-type busbar includes a first layer, a second layer, and a third layer for more efficient heat dissipation.

A power relay assembly is provided. A power relay assembly according to an exemplary embodiment of the present invention comprises: a support plate having at least one electric element mounted on one surface thereof and including a plastic material having heat dissipation and insulation properties; and at least one bus bar electrically connected to the electric element and partially embedded in the support plate. Due to these features, since heat generated from the bus bar and the electric element is dissipated to the outside through the support plate, it is possible to prevent performance deterioration due to heat and breakage of electronic components.

The invention relates to a modular and compact arrangement (200) of three phases (A, B, C) of a gas-insulated apparatus (100), that is suitable for placement inside a tunnel or a pipe (106) or another confined space. According to the invention, the three phases (A, B, C) are arranged in a triangle or side-by-side on a fixation part (103, 104) which includes a roller system (105; 105a, 105b, 105c, 105d). This allows the insertion of such a three-phase assembly (100) into confined spaces such as pipes or tunnels (106), without the need for access by workers or machinery. Furthermore, the present disclosure relates to a method for assembling and installing such a three-phase arrangement (100) into the confined space (106).