Thesis June-Hee Lee, “고효율 태양광 마이크로인버터 시스템의 제어기 설계,” 아주대학교 공학박사 학위 논문, 2018.
2018
본문
This paper proposes the design and control methods for photovoltaic microinverter systems. The microinverter is a type of photovoltaic
inverter that can be attached to
individual solar panels behind the railing at the array area. The microinverter
offers a much more
generation efficiency because it is
connected to each separate solar panel. Therefore, the other solar panels not
affected by shade or
debris can still produce maximum power.
In comparison, the central photovoltaic inverter is paired together so if shade
or debris is on
just one solar panel, the output power of
the entire inverter can be dramatically decreased. Two studies for the design
and control of
the miciroinverter are contained in this
paper: sensorless maximum power point traking (MPPT) method and dead-beat
control (DBC)
for the high efficiency microinverter.
Firstly, this paper proposes a current sensorless MPPT control method for the
microinverter system.
The conventional MPPT control method is
essential in photovoltaic power generation systems. After obtaining the value
from many
sensors, the system operates the P&O
MPPT control method. At this time, the expensive isolated voltage and current
sensor are used
in the microinverter system. In a small
photovoltaic power generation system, the cost and size of the microinverter
are important
factors to compete other products.
Therefore, by reducing the number of parts, for example the input current
sensor, the system
advantage is a smaller size and a lower
cost. Secondly, this paper proposes a method to reduce the distortion of the
grid current using
a DBC method for bridgeless inverter
systems. In the case of the general PI current controller for power factor correction
(PFC) scheme,
the grid current is generally distorted
due to the slow dynamic response of the PI controller. The PI current
controller is affected by
the bandwidth. If the bandwidth of the PI
controller increases to improve the dynamic response, the PI controller
performs a fast
dynamic response, but it becomes unstable
because the wide bandwidth leads to the control of unnecessary values such as a
grid
current noise. However, the proposed
PFC-DBC method has a fast response for the reference current and accuracy
compared to the
conventional PFC-PI controller due to the
optimal duty cycle for the next state reference current value. In addition,
since the inaccurate
system modeling due to the mismatch in
parameter, the proposed PFC-DBC controller can be unstable state. In this
paper,
the proposed PFC-DBC method can operate
robust control by using the estimation method for actual filter inductance. The
simulations are carried out to verify the
effectiveness of the proposed methods: sensorless MPPT method and PFC-DBC
method for
the high efficiency microinverter.
Moreover, the experiments are carried out to verify the performance and
effectiveness of the
proposed methods on a 110 [W] prototype
current-fed microinverter and 300 [W] voltage-fed microinverter.
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