Copper loss

(electricity) Power loss in a winding due to current flow through the resistance of the copper conductors. Also known as I²R loss.

The power loss due to the flow of current through copper conductors. When an electric current flows through a copper conductor (or any conductor), some energy is converted to heat. The heat, in turn, causes the operating temperature of the device to rise. This happens in transformers, generators, motors, relays, and transmission lines, and is a principal limitation on the conditions of operation of these devices. Excessive temperature rises lead to equipment failure.

Much research has been undertaken to reduce the loss in machines and thus to increase the output capability and efficiency for a given amount of conductor. For large machines and for transmission lines, the concept of superconductivity appears to hold much promise for substantial improvements in operating efficiencies. See also Superconducting devices.

Power lost in transformers, generators, connecting wires and other parts of a circuit due to current flow through the resistance of copper conductors.

Copper loss is the term often given to heat produced by electrical currents in the conductors of transformer windings, or other electrical devices. Copper losses are an undesirable transfer of energy, as are core losses, which result from induced currents in adjacent components. The term is applied regardless of whether the windings are made of copper or another conductor, such as aluminium. Hence the term winding loss is often preferred. A related term, load loss closely related but not identical, since an unloaded transformer will have some winding loss.

Copper losses result from Joule heating and so are also referred to as "I squared R losses", in deference to Joule's First Law. This states that the energy lost each second, or power, increases as the square of the current through the windings and in proportion to the electrical resistance of the conductors.

Copper Loss = I²R

where I is the current flowing in the conductor and R the resistance of the conductor. With I in amperes and R in ohms, the calculated power loss is given in watts.

With high-frequency currents, winding loss is affected by proximity effect and skin effect, and cannot be calculated as simply.

For low-frequency applications, the power lost can be minimized by employing conductors with a large cross-sectional area, made from low-resistivity metals.

See also

• iron loss

External links

• Reduction of copper losses

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