All Words
Exact Phrase
Title Search Only
advanced search
Digital Archives Initiative
Memorial University - Electronic Theses and Dissertations 5
Anthropology
Aquaculture
Archaeology
Biochemistry
Biology
Biopsychology
Chemistry
Classics
Community Health
Computational Science
Computer Science
Counselling Centre
Earth Sciences
Economics
Education
Educational Administration
Educational Psychology
Engineering
English
Environmental Science
Folklore
French and Spanish
Geography
German and Russian
History
Human Kinetics and Recreation
Linguistics
Marine Studies
Mathematics and Statistics
Medicine
Nursing
Pharmacy
Philosophy
Physics and Physical Oceanography
Political Science
Psychology
Religious Studies
Social Work
Sociology
Toxicology
Women's Studies
home
browse
preferences
my favorites
about/feedback
recent uploads
help/search tips
Français
menu off
add document to favorites
:
add page to favorites
:
reference url
back to results
:
previous
:
next
Search this object:
0
hit(s) ::
previous hit
:
next hit
View:
document description
page description
page & text
previous page
:
next page
Document Description
Title
Adaptive
power
tracking
control
of
hydrokinetic
energy
conversion
systems
Author
Khan
,
Mohammad
Jahangir
Alam
Description
Thesis
(Ph.D.)--Memorial
University
of
Newfoundland
,
2010.
Engineering
and
Applied
Science
Date
2010
Pagination
xxiv, 316 leaves : ill. (chiefly col.).
Subject
Direct
energy
conversion;
Hydraulic
turbines--Design
and
construction;
Power
electronics;
Water-power
Degree
Ph.D.
Degree Grantor
Memorial University of Newfoundland. Faculty of Engineering and Applied Science
Discipline
Engineering and Applied Science
Language
Eng
Notes
Bibliography:
leaves
287-304.
Abstract
Hydrokinetic
energy
conversion
systems
(HECS)
are
electromechanical
devices
that
operate
in
free-stream
water
channels
in a
manner
similar
to
wind
turbines.
The
fundamental
process
of
fluid-mechanic
energy
conversion
using
a
hydrokinetic
turbine
is
manifested
through
a
nonlinear
performance
characteristics.
The
problem
of
maximum
power
tracking
evolves
around
this
nonlinearity
and the
underlying
control
objective
is
to
regulate
the
turbine's
operating
conditions
such
that
system
efficiency
is
in the
neighborhood
of the
optimum
point.
Through
this
research
,
it
has been
identified
that a
power
tracking
method
that
is
independent
of the
turbine's
characteristics
,
which
can
be
implemented
without
using
underwater/mechanical
sensors
would be of
significant
interest
to the
emerging
hydrokinetic
energy
technologies.
Further
to a
comparative
analysis
of
various
traditional
wind
turbine
control
techniques
, an
adaptive
tracking
approach
termed
as
'extremum
seeking
control'
(ESC)
approach
has been
adopted.
Detailed
mathematical
formulations
pertaining
to this
novel
control
solution
has been
provided
and
relevant
parameter
tuning
and
implementation
procedures
are
presented.
--
In
order
to
provide
sufficient
insight
into the
design
,
operation
, and
control
aspects
of a
real-life
hydrokinetic
system
, a
small-scale
vertical
axis
turbine
has been
developed
in this
work.
This
turbine
employs
a
multi-pole
permanent
magnet
alternator
for
electromechanical
energy
conversion.
A
ac-dc-ac
power
electronic
stage
interfaces
the
asynchronous
output
of the
generator
to the
utility
grid
through
a
single-phase
connection.
Even
though
a
stand-alone
test
setup
is
possible
, the
grid-tied
option
has been
pursued
for
ease
of
implementation
as
well
as to
explore
broader
areas
of
deployment.
In
addition
to
modeling
and
validating
all
the
subsystems
in the
laboratory
, the
turbine
rotor
system
has been
tested
under
controlled
environment
in a
tow
tank.
Associated
numerical
models
have been
validated
extensively
prior
to their
use
in the
power
tracking
control
study.
In
addition
,
simulation
schemes
for
hydrological
flow
fields
and
rotor
fluid-dynamic
characteristics
have been
developed
as
aiding
tools
to this
research.
--
The
extremum
seeking
controller
parameter
tuning
and
implementation
method
developed
in this
work
, has been
found
to be
capable
of
successfully
regulating
the
system
operating
condition
at the
optimum
point.
This
method
requires
minimal
information
on the
hydrokinetic
device's
operational
characteristics
and
can
be
potentially
deployed
in
wide
range
of
devices.
Further
work
within
this
research
track
includes
,
implementation
of the
ESC
method
in
mid
to
large-sized
hydrokinetic
systems
and
development
of
multi-objective
control
solutions.
As a
continuation
of this
research
,
active
efforts
are
currently
being
made
such
that the
true
potential
of the
extremum
seeking
control
and
other
advanced
power
tracking
techniques
can
be
realized
in
near-future.
Type
Text
Resource Type
Electronic
thesis
or
dissertation
Format
Image/jpeg;
Application/pdf
Source
Paper copy kept in the Centre for Newfoundland Studies, Memorial University Libraries
Local Identifier
a3506849
Rights
The author retains copyright ownership and moral rights in this thesis. Neither the thesis nor substantial extracts from it may be printed or otherwise reproduced without the author's permission.
Collection
Electronic
Theses
and
Dissertations
Scanning Status
Completed
PDF File
(21.56
MB)
--
http://collections.mun.ca/PDFs/theses/Khan_MohammadJahangirAlam.pdf
CONTENTdm file name
10676.cpd
