ABSTRACT:
This paper presents a new asymmetrical singlephase multilevel
inverter topology capable of producing ninelevel output voltage with reduce
device counts. In order to obtain the desired output voltage, dc sources are
connected in all the combination of addition and subtraction through different switches.
Proposed topology results in reduction of dc source, switch counts, losses,
cost and size of the inverter. Comparison between the existing topologies shows
that the proposed topology yields less component counts. Proposed topology is
modeled and simulated using Matlab-Simulink software in order to verify the performance
and feasibility of the circuit. A low frequency switching strategy is also
proposed in this work. The results show that the proposed topology is capable
to produce a nine-level output voltage with less number of component counts and
acceptable harmonic distortion content.
KEYWORDS:
1.
Multilevel inverter
2.
Asymmetrical
3.
Total Harmonic Distortion (THD)
4.
Low-frequency switching
SOFTWARE: MATLAB/SIMULINK
Fig.
1. Proposed nine level inverter topology.
Fig.
2. Simulation results for proposed nine level inverter topology; (a)
and
(b) are switching pulses, (c) Level generator output voltage.
Fig.
3. Simulation Output results at 50Hz fundamental frequency for R = 150ohm, L=
240, P.F = 0.9
Fig.
4. Simulation Output results at 50Hz fundamental frequency for R =150ohm, L=
240, P.F = 0.9
CONCLUSION:
In
this paper a new single-phase multilevel inverter topology is presented.
Proposed topology is capable of producing nine-level output voltage with reduce
device counts. It can be used in medium and high power application with unequal
dc sources. Different modes of operation are discussed in detail. On the bases
of device counts, the proposed topology is compared with conventional as well
as other asymmetrical nine-level inverter topologies presented in literature.
Comparative study shows that, for nine level output, the proposed topology
requires lesser component counts then the conventional and other topologies.
Proposed circuit is modeled in Matlab/Simulink environment. Results obtained shows
that topology works properly. Detailed Simulation analysis is carried out. THD
obtained in the output voltage is 8.95% whereas the each harmonic order is <
5%, satisfies harmonic Standard (IEEE-519).
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