Corona discharge is a phenomenon that occurs in high-voltage AC (alternating current) transmission lines when the electric field strength surrounding the conductor exceeds a certain threshold value. It is characterized by the ionization of air molecules around the conductor, leading to the formation of a faint bluish or purplish glow, often accompanied by a hissing or crackling sound.
When high-voltage AC power is transmitted through transmission lines, an electric field is generated around the conductors due to the potential difference between them. If the electric field strength becomes high enough, it can cause the air molecules in the vicinity of the conductor to lose electrons, resulting in the formation of ions – positively charged ions (cations) and negatively charged ions (anions). These ions are attracted to the conductor due to the opposite electric charges, and they migrate towards the conductor.
There are a few key points to understand about corona discharge:
Electric Field Intensity: As the voltage on the transmission lines increases, the electric field strength around the conductor also increases. At a certain point, known as the corona onset voltage, the electric field strength becomes sufficient to initiate ionization of air molecules near the conductor's surface.
Ionization: When the air molecules lose electrons, they become ions. This ionization process requires energy, and that energy is often obtained from the electric field itself. The liberated electrons can be accelerated in the electric field and collide with other molecules, causing a chain reaction of ionization.
Glow and Sound: The ionization of air molecules produces a faint bluish or purplish glow known as corona glow. Additionally, the movement of ions in the electric field can lead to collisions between them and with other air molecules, creating a hissing or crackling sound.
Power Loss and Efficiency: Corona discharge consumes some energy from the power being transmitted, converting it into heat and light. This results in a small loss of power and reduces the overall efficiency of the transmission system. In extreme cases, excessive corona discharge can lead to increased energy losses, radio interference, and even damage to the transmission line insulation.
Reducing Corona Effects: Engineers take several measures to minimize the effects of corona discharge in high-voltage AC transmission lines. These include using conductors with larger diameters, optimizing the spacing between conductors, and designing insulator shapes that help distribute the electric field more evenly.
In summary, corona discharge is a phenomenon that occurs in high-voltage AC transmission lines when the electric field strength reaches a critical value, causing ionization of air molecules around the conductors. While it can lead to energy losses and other undesirable effects, careful design and engineering practices can help mitigate its impact on the efficiency and reliability of the power transmission system.