A product distribution splitter has a main body circumscribed by a plurality of sidewalls with an electric input port extending from one of the sidewalls for receiving high wattage electrical power from an electrical power source and electrical power reduction means in the form of an IC electrical circle board for receiving the high wattage electrical power and outputting lower wattage electrical power. A cavity is located through another of the sidewalls, the cavity containing electrical conductive prongs which extend from the IC electrical circle board. The prongs receive the lower wattage electrical power and can output this power to a second PDS. Electrical wiring connected to the electrical circle board extends through a third sidewall and is attached to an electrical connector for transmitting the lower wattage electrical power to electrical circuitry.

A product distribution splitter has a main body circumscribed by a plurality of sidewalls with an electric input port extending from one of the sidewalls for receiving high wattage electrical power from an electrical power source and electrical power reduction means in the form of an IC electrical circle board for receiving the high wattage electrical power and outputting lower wattage electrical power. A cavity is located through another of the sidewalls, the cavity containing electrical conductive prongs which extend from the IC electrical circle board. The prongs receive the lower wattage electrical power and can output this power to a second PDS. Electrical wiring connected to the electrical circle board extends through a third sidewall and is attached to an electrical connector for transmitting the lower wattage electrical power to electrical circuitry.

A bus bar assembly is provided and includes a first linking bus bar, a second linking bus bar and plural power connectors. The first linking bus bar includes a first main bar, a first bending part, a first conducting part and plural second conducting parts. The second conducting parts connect with the first main bar, respectively. The first bending part connects between the first main bar and the first conducting part. The second linking bus bar is disposed corresponding to and isolated from the first linking bus bar, and includes a second main bar, a second bending part, a third conducting part and plural fourth conducting parts. The fourth conducting parts connect with the second main bar, respectively. The second bending part connects between the second main bar and the third conducting part. The power connectors are electrically coupled with the second conducting parts and the fourth conducting parts.

A bus bar assembly is provided and includes a first linking bus bar, a second linking bus bar and plural power connectors. The first linking bus bar includes a first main bar, a first bending part, a first conducting part and plural second conducting parts. The second conducting parts connect with the first main bar, respectively. The first bending part connects between the first main bar and the first conducting part. The second linking bus bar is disposed corresponding to and isolated from the first linking bus bar, and includes a second main bar, a second bending part, a third conducting part and plural fourth conducting parts. The fourth conducting parts connect with the second main bar, respectively. The second bending part connects between the second main bar and the third conducting part. The power connectors are electrically coupled with the second conducting parts and the fourth conducting parts.

A system and method are provided for coordinating the installation and removal a motor control center subunit with the power connection and interruption thereof. A system of interlocks and indicators causes an operator to install a motor control center subunit into a motor control center, and connect supply and control power thereto, in a particular order. Embodiments of the invention may prevent actuation of line contacts of the bucket, and shield the line contacts, until the bucket is fully installed in the motor control center. Other embodiments also prevent circuit breaker closure until the line contacts are engaged with a bus of the motor control center.

A system and method are provided for coordinating the installation and removal a motor control center subunit with the power connection and interruption thereof. A system of interlocks and indicators causes an operator to install a motor control center subunit into a motor control center, and connect supply and control power thereto, in a particular order. Embodiments of the invention may prevent actuation of line contacts of the bucket, and shield the line contacts, until the bucket is fully installed in the motor control center. Other embodiments also prevent circuit breaker closure until the line contacts are engaged with a bus of the motor control center.

A power distribution unit (PDU) comprises a housing, an input on the housing, and an input connector coupled to the input on the housing. The input connector is connectable to a power source that provides power for distribution by the PDU to one or more power consuming devices. The PDU includes an output including output connectors that provide blind-mate connection with a connection interface coupled to the one or more power consuming devices.

Currents may be balanced in an apparatus including first and second conductors electrically connected to a third conductor and configured to be coupled to respective first and second parallel-connected circuit breaker switches using at least one magnetic core positioned adjacent at least one of the first and second conductors to introduce an inductance in the at least one of the first and second conductors. The at least one core may include at least one magnetic material ring that at least partially surrounds the at least one of the first and second conductors. The at least one magnetic material ring may include a plurality of laminated layers of grain-oriented steel.

Currents may be balanced in an apparatus including first and second conductors electrically connected to a third conductor and configured to be coupled to respective first and second parallel-connected circuit breaker switches using at least one magnetic core positioned adjacent at least one of the first and second conductors to introduce an inductance in the at least one of the first and second conductors. The at least one core may include at least one magnetic material ring that at least partially surrounds the at least one of the first and second conductors. The at least one magnetic material ring may include a plurality of laminated layers of grain-oriented steel.

A filling device for the joint that provides filling of the desired area to be poured in cases where similar electrical transmission systems or components such as low and high voltage busbars and cables are attached to each other.