A dynamic wireless electric vehicle charging system with uniform coupling factor and negligible power / Md Morshed Alam
To minimize the dependency on the petroleum products, electric vehicles (EV) have been selected as a feasible solution for transportation purpose. EV was introduced with the appearance of the hybrid electric vehicle (HEV), which causes to bring the development of plug-in hybrid electric vehicles...
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| Format: | Thesis |
| Published: |
2018
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| Subjects: | |
| Online Access: | http://studentsrepo.um.edu.my/9094/2/MD_MORSHED_ALAM.bmp http://studentsrepo.um.edu.my/9094/11/morshed.pdf http://studentsrepo.um.edu.my/9094/ |
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| Summary: | To minimize the dependency on the petroleum products, electric vehicles (EV) have been
selected as a feasible solution for transportation purpose. EV was introduced with the
appearance of the hybrid electric vehicle (HEV), which causes to bring the development of
plug-in hybrid electric vehicles (PHEVs). On the other hand, PHEV is responsible for
various drawbacks such as the necessity of connecting cables and plug in charger, galvanic
isolation of on-board electronics, the weight and size of the charger, and more important
safety issues associated with the operation in the rainy and snowing condition. For user
friendly and any prevention from the risk by electricity, inductive power transfer (IPT)
method has emerged to charge the EV inductively over the large air gap. There are two
types of IPT based EV charging system: stationary and dynamic. High efficiency inductive
power transfer (IPT) with low misalignment effect is one of the key issues for the dynamic
charging electric vehicle (EV) system. This research presents an advanced concept of
analysis and design of transmitter and receiver pads with a special arrangement of pad
assembly for dynamic charging of EV. In each transmitter pad, the large rectangular section
is series connected with two zigzag- shaped small rectangular sections. These small
sections are back-to-back series connected and located inside the large rectangular section.
An adjacent pair of proposed transmitter pad with back-to-back series connection, named
as extended DD transmitter is used throughout this work. One of the contributions of this
work is uniform surface magnetic flux distribution, obtained by the zigzag-shaped
rectangular sections. Designing of the proposed transmitter and receiver with the simulation
results are done by the 2-D finite element analysis (FEA). In the case of extended DD
transmitter, negligible power transfer fluctuation is the major contribution regardless of the
horizontal (x-direction) misalignment of the receiver pad. Justification of the pad design is performed with the load independent voltage gain and power transfer fluctuation
characteristics. A compensation technique named LC-LC2 is used in order to obtain the
load independent operation and the better tolerance of the air gap variation. Experimental
results prove that power transfer fluctuation with load independent unique voltage gain is
within ±6% and efficiency is about 93% under any horizontal (x-direction) misalignment
condition of the receiver pad with an air gap of 140mm. |
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