This invention refers to a detachable carbon-fiber conductive rail in the technical field of conductive rail. The conductive rail above has a main body that consists of a long connecting pipe module linked with an elastic sheet module at one end, and at the other end of the elastic sheet module far away from the long connecting pipe module, there is a short connecting pipe module. In this invention, the long connecting pipe module, the elastic sheet module and the short connecting pipe module are connected in sequence. In this way, operators can dismount and install the modules easily to improve efficiency of installation and bring down the costs. As for this detachable carbon-fiber conductive rail, multiple long connecting pipe modules, elastic sheet modules and short connecting pipe modules can be connected together in sequence to shape several conductive rails. The installation circuits can be curved, straight or annular. Both the long and short connecting pipes are made of carbon-fiber composites which are characterized by strong resistance to thermal shock, corrosion and radiance.

Provided is a circuit assembly that can prevent a switching element from overheating. Included is a first conductive portion that is plate-shaped and elongated in one direction, a second conductive portion that is plate-shaped, elongated along a lengthwise direction of the first conductive portion, and is arranged to be separated from the first conductive portion by a predetermined distance, and a plurality of switching elements that are arranged straddling the first conductive portion and the second conductive portion, and are lined up in the lengthwise direction, wherein width of the first conductive portion or the second conductive portion at one end portion in the lengthwise direction is different from a width at the other end portion in the lengthwise direction.

An electrical load center includes a first mounting rail supporting a first row of circuit breakers, and a second mounting rail supporting a second row of circuit breakers. The load center also includes a first neutral bus bar spaced apart from the first mounting rail, a rail-to-rail link electrically coupled between the first mounting rail and the second mounting rail, and a first rail-to-neutral link electrically coupled between a first end of the rail-to-rail link and the first neutral bus bar.

An electrical conductor assembly for use in a power distribution assembly includes an electrical conductor. A casing covers at least a portion of the electrical conductor. The casing insulates the at least a portion of the electrical conductor.

A jumper is adapted to be disposed between two sockets. Each of the sockets has at least one conductive terminal. The jumper includes an insulative body and at least one conductive body, which includes a main body portion, a first engaging portion, and a second engaging portion. The main body portion is connected to the insulative body. The first and second engaging portions are respectively located at two opposite sides of the main body portion, and extend respectively from two opposite sides of the insulative body. The first engaging portion engages the conductive terminal of one of the sockets. The second engaging portion engages the conductive terminal of another one of the sockets, such that the conductive terminals are electrically connected. A power distribution device is also provided.

A motor includes a stator including, a rotor to rotate about a central axis extending in a vertical direction, and a first bus bar, a second bus bar, and a third bus bar to which lead wires of the coils are respectively connected. The first bus bar includes a first connecting portion to which two lead wires are connected, the second bus bar includes a second connecting portion to which two lead wires are connected, the third bus bar includes a third connecting portion to which one lead wire is connected and a fourth connecting portion to which one lead wire is connected. The first and second connecting portions are arranged side by side in a circumferential direction, and the third and fourth connecting portions are arranged in the circumferential direction with the first and second connecting portions interposed therebetween.

The invention relates to an electrical distribution system (1), having a housing (3), in which fastening rails (13) are provided, which provide fastening points (15), which are arranged in lines, for the fastening of electrical components (17). Additionally, one or more, in particular explosion-protected, line-shaped heating elements (19) are provided in the housing (3), which heating elements each comprise a radiator body (23). The one or more heating elements (19) are each arranged below an associated group of fastening points (15), where electric current can be applied to the heating elements in order to heat electrical components (17) fastened at the associated fastening points (15).

A cable manager includes one or more cable manager units. Each cable manager unit includes a pair of side cable guides, each comprised of a plurality of finger-like projections extending forwardly from a support column. At least one of the pair of support columns has a socket arranged at a side thereof. Each cable manager unit further includes a separate midsection member capable of insertion into the socket for interconnecting the pair of side cable guides.

A laminated busbar assembly includes a substrate, a positive current metal plate provided with a first pin, a negative current metal plate provided with a second pin, and an output current metal plate provided with a third pin. The substrate is provided with a pad hole group including a first pad hole, a second pad hole, and a third pad hole. The pad hole group is electrically connected to copper cladded on the substrate to form wirings. The positive current metal plate, the negative current metal plate, and the output current metal plate re all arranged on the first side of the substrate in a laminated manner. The first pin passes through first pad hole, the second pin passes through the second pad hole, and the third pin passes through the third pad hole.

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 are connected to sub-distribution rails. In at least a first plane, said sub-distribution rails extend substantially in parallel to the main plane and are 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, are 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.