| dc.description.abstract | Grid reliability and power outages are key concerns today, due to the ever-increasing energy
demand. Traditionally, Uninterruptible Power Supplies (UPS) with battery storage have been
employed to contend with grid outages. For renewable power production, Solar-Photovoltaics
(SPV) based Distributed Energy Resources (DERs) have been integrated with the grid using a
power electronic Grid-Tied Inverter (GTI). A typical GTI by design, engages in power conversion only when the grid is present, and ceases operation during a power outage to avoid a local
unintentional island formation. Thus, solar energy is left unutilized by the GTI during a power
outage, where the UPS steps in, to power critical loads. Recently, hybrid-PV or dual-mode
inverter systems, that combine the complementary functional properties of UPS and GTI, have
been in the focus of research due to their ability of standalone system operation during an
outage while accessing solar power. Such a hybrid approach, although meets the desired operational objectives, requires the design, sizing, and control of the entire system, that comprises
of multiple power converters, battery-banks, and SPV, to be carried out in a unified manner.
This work enhances the existing methods of solar energy access during a power outage,
where the GTI is kept as an independent system from the UPS. A reconfigurable battery/grid
tied inverter (RBGTI) scheme is proposed, that ties to the grid and functions as a regular DCAC GTI when grid is present. However, during a power outage, it reconnects to the batterybank of an existing UPS present in a facility, where it functions as a DC-DC converter to provide
PV based energy support. However, such an operation of RBGTI requires several questions to
be resolved in terms of hardware configuration, islanding behavior, battery management, and
overall system control, which are addressed in this work.
For the islanding behavior in grid-tied mode, a dynamic-phasor based GTI system model
is proposed that captures the system dynamics accurately after unintentional islanding and
allows systematic stability study based on eigenvalue analysis. In the battery-tied mode, a
dynamic model of the PV fed battery charge-controller system is proposed which facilitates the
systematic design of a maximum-power-point tracking (MPPT) controller and a load current
tracking controller for the RBGTI, that achieves the effect of a virtual PV based batterybank in parallel with the physical UPS battery. A supervisory RBGTI control scheme is
proposed that ensures stable system operation during dynamic conditions of load power and
solar insolation changes while reducing discharge burden on the UPS battery. A discrete IGBT
converter hardware platform is developed, where the proposed analytical models, controls and
the RBGTI performance are verified on a 4.5 kW experimental setup | en_US |
