A current transformer (CT) is an electrical device used to measure high currents accurately by converting them into lower, manageable currents that can be safely measured by instruments and meters. It is commonly used in power systems, electrical substations, and industrial applications for monitoring and protection purposes. Here's how a current transformer works for current measurement:
Basic Construction: A current transformer consists of a primary winding and a secondary winding. The primary winding is a single or multi-turn coil that is connected in series with the high-current carrying conductor that needs to be measured. The secondary winding is a large number of turns of fine wire wound on a laminated core.
Mutual Induction: The key principle behind the operation of a current transformer is mutual induction. When a high current flows through the primary winding, it creates a varying magnetic field around the conductor. This magnetic field then induces a proportional voltage across the secondary winding through mutual induction.
Turns Ratio: The turns ratio of the transformer determines the relationship between the primary and secondary currents. For example, if the turns ratio is 1:100, and the primary current is 1000 amps, the secondary current will be 10 amps (1000 A / 100 = 10 A). The secondary current is thus a reduced replica of the primary current.
Current Isolation: The current transformer provides electrical isolation between the high-current primary circuit and the low-current secondary circuit. This isolation is crucial for safety reasons, ensuring that instruments and meters connected to the secondary side are not exposed to the high currents on the primary side.
Burden: The burden is the impedance of the secondary winding and any connected measuring instrument. It is essential to ensure that the burden is within the specified range of the CT to maintain measurement accuracy.
Accuracy: Current transformers are designed to be highly accurate over a wide range of currents. The accuracy is usually specified as a percentage of the rated primary current, and precision classes are used to define the level of accuracy (e.g., 0.1, 0.2, 0.5, 1.0, etc.).
Usage: Current transformers are commonly used with various instruments, such as ammeters, wattmeters, energy meters, protection relays, and other devices that require current measurements.
In summary, a current transformer works by utilizing mutual induction to convert high currents into proportional lower currents for measurement and protection purposes. Its ability to accurately and safely measure high currents makes it a critical component in electrical power systems and industrial applications.