A bidirectional LLC resonant converter with synchronous rectification and adaptive feedback control is a power electronics topology used for high-frequency power conversion. This converter can efficiently transfer power bidirectionally between two power domains (e.g., a battery and a DC bus) while maintaining good regulation and minimizing losses. Let's break down its working step-by-step:
Basic Structure:
The bidirectional LLC resonant converter consists of an inductor (L), a capacitor (C), and a resonant tank circuit (consisting of a resonant capacitor and resonant inductor) on the primary side, along with synchronous rectifiers on both the primary and secondary sides. The converter can operate in both buck and boost modes, depending on the voltage levels on the primary and secondary sides.
Synchronous Rectification:
Synchronous rectification means using active switches (usually MOSFETs) as rectifiers on both the primary and secondary sides, instead of diodes used in traditional rectifiers. These active switches allow bidirectional power flow and reduce the conduction losses in the converter, improving overall efficiency.
LLC Resonant Converter Operation:
The LLC resonant converter operates at high frequencies and utilizes resonant tank circuits to achieve soft switching. This means that the switches (MOSFETs) turn on and off when there is minimal voltage across them, reducing switching losses and improving efficiency.
During the first half of the switching cycle, the primary-side MOSFETs (switches) are turned on, and current starts to flow through the primary inductor (L) and the primary-side resonant capacitor (Cres). This builds energy in the magnetic field of the inductor and charges the resonant capacitor.
When the voltage across the primary-side resonant capacitor reaches a certain threshold, the primary-side switches are turned off. The energy stored in the magnetic field of the inductor causes the current to continue flowing, charging the primary-side resonant inductor (Lres) and the secondary-side resonant capacitor (Cres).
During the second half of the switching cycle, the primary-side switches remain off, and the secondary-side MOSFETs are turned on. The resonant energy from the primary side is transferred to the secondary side, where it is rectified and used to charge the output capacitor (Cout) and supply the load.
The process repeats at the resonant frequency, with the switches on both sides being driven in a manner that maintains the desired output voltage.
Bidirectional Operation:
The bidirectional capability is achieved by controlling the duty cycle of the primary-side switches. Depending on the power flow direction (buck or boost mode), the duty cycle is adjusted to regulate the output voltage. In buck mode, power is transferred from the input to the output, and in boost mode, power flows from the output to the input.
Adaptive Feedback Control:
The adaptive feedback control is a control system that monitors the output voltage and adjusts the duty cycle of the primary-side switches to maintain a constant output voltage even under varying load conditions. The control system continuously adjusts the duty cycle based on the feedback signal, ensuring stable and efficient operation.
In summary, a bidirectional LLC resonant converter with synchronous rectification and adaptive feedback control operates at high frequencies using resonant tank circuits to achieve soft switching. The synchronous rectification reduces conduction losses, and the adaptive feedback control ensures stable and efficient power transfer bidirectionally between two power domains.