Synchronous generators are a key component of AC power systems, commonly used in electricity generation. Maintaining synchronism is crucial to ensure stable and reliable power delivery to the grid. Synchronous generators maintain synchronism with the AC power system through various mechanisms:
Frequency Control: The frequency of an AC power system is determined by the rotational speed of the synchronous generator's rotor. Synchronous generators are designed to run at a specific speed (synchronous speed) to generate power at a desired frequency (e.g., 50 Hz or 60 Hz). Any deviation in generator speed from the grid frequency will result in a loss of synchronism. To maintain synchronism, the generator's mechanical speed is controlled using prime movers (such as steam turbines, gas turbines, or hydro turbines) that are designed to respond to changes in load and grid frequency.
Automatic Voltage Regulators (AVRs): Synchronous generators are equipped with Automatic Voltage Regulators (AVRs) that control the generator's terminal voltage. These AVRs monitor the generator's output voltage and adjust the excitation (field current) applied to the generator's rotor to maintain a consistent terminal voltage. A stable voltage helps the generator stay in synchronism with the grid and ensures proper power transfer.
Governor Control: The prime mover driving the generator (e.g., steam turbine or gas turbine) is equipped with a governor control system. The governor senses changes in grid frequency and adjusts the prime mover's output to bring the generator speed back to the synchronous speed. This helps maintain the desired grid frequency and synchronism.
Load Sharing: In a power system with multiple synchronous generators, load sharing among generators is essential to maintain synchronism. Control systems are employed to balance the load between generators based on their capacities and operational characteristics. If one generator starts to take more load than others, it can lead to a deviation in its speed and frequency, potentially causing loss of synchronism.
Protection Systems: Synchronous generators are equipped with protection systems that detect abnormal operating conditions, such as overloads, faults, or disturbances. These protection systems can trigger actions to disconnect the generator from the grid to prevent damage or loss of synchronism. Rapid and accurate protection systems are crucial for maintaining stable operation.
Communication and Control: Modern power systems use advanced communication and control technologies to monitor and manage the operation of synchronous generators. Supervisory control and data acquisition (SCADA) systems, digital control systems, and sophisticated algorithms help operators maintain synchronism by continuously monitoring and adjusting generator parameters.
In summary, synchronous generators maintain synchronism with the AC power system through a combination of frequency control, voltage regulation, governor control, load sharing, protection systems, and advanced communication and control technologies. These mechanisms work together to ensure stable and reliable power generation and delivery to the grid.