Abstract:
The Interface inverters arbitrate the network impedance based on the source
characteristics for efficient solar energy harvesting. The wide impedance arbitration
capability of the interface inverter defines the wide operational integrity with the AC
network. In the weak grid scenario, the uncompensated grid inductance beyond PCC
offers the negative damping for power oscillations at the point of common coupling
(PCC) tugs the system towards instability. In this research work, the negative damping
influence due to interactions between the system impedance (filter inductance and
grid power injection resistance) and AC network impedance (grid inductance) on the
inverter closed-loop controller is characterized by observing the natural phase deviations
in real and imaginary axis. Through distinguished system’s natural response, a novel
second-order system impedance model is derived, and proposed current controller gain
characterization aiming to achieve positive damping to mitigate the PCC’s oscillations.
Further tuning of the controller based on the natural response of the derived impedance
model accomplishes the enhanced grid injected power quality. The efficacy of the derived
system impedance model along with coherence of current controller gain is demonstrated
on hardware for enhanced power quality under the stable operating region.Apart from
this , a new series solar inverter configuration is proposed to share the power in terms
of voltage, unlike parallel inverter configurations. In a single-stage parallel inverter,
elevated DC potential and circulating current due to common-mode voltage (CMV)
would degrade the solar inverter’s life. The proposed topology eases the stress on the
DC bus and protects the solar inverter from the issues associated with elevated DC
potential (Potential induced degradation effect, switch operating voltage stress, etc.). The
inherent boosting capability of the proposed series inverter with two modular inverters
is demonstrated through two switching algorithms. In the first switching algorithm, the
switching combinations are devised to yield the maximum voltage across the load. The
second switching algorithm demonstrates the method of eliminating CMV by choosing the
appropriate switching combination of two inverters. The eliminated instantaneous CMV
would give the provision of operating proposed topology with common DC bus along
with the flexibility of DC bus grounding. For the proposed configuration with devised
switching techniques, the closed-loop controller is designed by computing the plant’s
equivalent characteristic impedance using a state-space model. The effectiveness of the
proposed configuration, along with the closed-loop control, is validated through hardware.
Also the multi boost solar inverter topologies of three variants are presented for grid
connected applications. Since the proposed topologies aim to achieve higher voltage boost
at AC side with reduced DC bus potential, it is required to use asynchronous switching
strategies, unlike parallel inverter configurations. Although the proposed topologies
are advantageous in-terms of improved reliability of solar panels and inverter modules,
but instantaneous characteristic impedance imbalance due to asynchronous switching
provokes circulating current within the inverter modules. Since the circulating current
is undesirable concerning power quality and thermal aspects, in this research work, the method of instantaneous impedance balance is ensured with the specially designed
switching algorithm for proposed topologies. The eliminated instantaneous circulating
current provide the flexibility of operating all inverter modules with the common DC
bus. The proposed high gain boost configurations and switching methodologies are
demonstrated on hardware prototype by pumping 2.4 kW power to the grid.