Leakage current is a common issue in electrical systems and can lead to serious accidents, loss of life, and property damage if not properly managed. Legal regulations mandate observation and precautionary measures to mitigate these risks. To understand leakage current, it is essential to define it. If the vector sum of the phase currents and the neutral return current is zero, there is no leakage current. However, if the neutral current is less than the total current from the phases, it indicates that some current has found an alternative path. This path could be through a person, an isolated point, or other hardware. Such issues often arise in electrical devices with insufficient insulation, manufacturing defects, or outdated technology.
When faulty devices are integrated into systems like electric panels, they can cause problems for surrounding equipment. It is crucial to measure and detect leakage currents before taking preventive actions. Immediate intervention is necessary when leakage is detected. Measurement and interruption can be performed using directly connected devices at low current levels. These devices, typically set at 30mA for personal safety and 300mA for fire prevention, are widely used in various applications.
In high current measurements, direct connection is not always feasible. In such cases, current transformers, similar to those used with energy meters or analyzers, are employed. Toroidal current transformers are particularly common. The principle involves passing each current through the transformer and taking measurements on the secondary side according to the winding ratio.
Leakage current measurement serves to protect systems. To measure the current difference as described earlier, the vector sum of the total input currents and the neutral currents must be measured. Therefore, all phase and neutral cables are passed together through these toroidal current transformers. The size of the transformers varies based on cable thickness, and openable types facilitate maintenance and troubleshooting. Once the cables are passed through the transformer, the secondary side is ready for measurement.
After measuring the current value, the leakage current must be checked. Leakage current relays are used for this purpose, often featuring adjustable trip times. Depending on the system's application, the permissible leakage current level might exceed the standard 30mA and 300mA thresholds. Adjustable relays allow users to set appropriate limits, which can be increased up to 250A. Some toroidal current transformers are integrated with the relay, simplifying panel design and installation. The relay output directly controls circuit breakers or contactors, ensuring system protection.
In panels with thick cables or bare conductors carrying high currents, passing them through toroidal current transformers can be challenging. Collector leakage current transformers offer a solution by measuring lines with X/5 current transformers, which then feed into the collector leakage current transformer.
A publication in the official newspaper on July 17, 2013, mandated that workplace main boards and secondary electrical panels be equipped with leakage current relays (residual current devices) following the principle of selectivity. This highlights the importance of implementing the correct solutions in the appropriate locations to ensure safety and compliance.