REDUCTION DES PERTES A VIDE DES TRANSFORMATEURS DE DISTRIBUTION PAR UTILISATION DE RUBANS AMORPHES by Malick MOUHAMAD

THESE DE DOCTORAT
DE L’ECOLE NORMALE SUPERIEURE DE CACHAN
Présentée par
Malick MOUHAMAD
pour obtenir le grade de
DOCTEUR DE L’ECOLE NORMALE SUPERIEURE DE CACHAN
Domaine :
ELECTRONIQUE – ELECTROTECHNIQUE – AUTOMATIQUE
REDUCTION DES PERTES A VIDE DES TRANSFORMATEURS DE DISTRIBUTION PAR UTILISATION DE RUBANS AMORPHES
Thèse présentée et soutenue à Cachan le 28/02/2012 
Abstract
This PhD dissertation deals with the application of amorphous ribbons in distribution transformer cores in order to reduce network losses.
The material is an alloy from iron, boron and silicon compounds. The first results on the material reveal a good physicochemical compatibility with tested transformer dielectric fluids. It should be noted these materials possess a far longer life than the transformer itself.
The potential for reducing losses from distribution transformers is considered as one element of EU and national strategies on energy efficiency. Losses generated through amorphous transformers are twice less than conventional ones.
Amorphous ribbon units represent a significant new advance in transformer technology and losses reduction. The investment, put to purchase the product, can be easily gained by the capitalisation of losses. The return can be achieved in 10 to 12 years, depending on the purchase price.
It is expected that a transformer will be subjected to a number of short-circuits during its service life, but sooner or later one such event will cause some slight winding movement, and the ability of the transformer to resist further short-circuits will then be severely reduced.
Amorphous metal distribution transformers (AMDT) is no exception and they should be able to resist electrodynamic forces during short-circuit test and match ERDF specifications. In fact, during SC, extreme electrodynamic forces cause the windings to deform and this shape deformity creates a lot of shear stress on amorphous cores which lead to break-up of some ribbons. The active part of an amorphous transformer should be strong enough to resist these stresses.
In fact, the behaviour of the core materials under short circuit currents depends especially on the know-how of manufacturers who can outline electrodynamic stress inside transformers. Concept design and processes have been improved in order to provide reliable devices but the task is not completely done yet.
Short-circuit withstand is one of the most important aspects which will approve this technology.
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http://innovation.edf.com/fichiers/fckeditor/Commun/Innovation/theses/TheseMouhamad.pdf

HIGH PERFORMANCE CONTROL OF A THREEPHASE PWM RECTIFIER YIN BO NATIONAL UNIVERSITY OF SINGAPORE

HIGH PERFORMANCE CONTROL OF A THREEPHASE
PWM RECTIFIER
YIN BO
(M.Eng.， Wuhan University，China)
A THESIS SUBMITTED
FOR THE DEGREE OF DOCTOR OF PHILOSOPHY
DEPARMENT OF ELECTRICAL AND COMPUTER ENGINEERING
NATIONAL UNIVERSITY OF SINGAPORE
2008
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http://www.mediafire.com/?1lvzrknovicuth2

New Energy-efficient High-voltage DC-DC Power Conversion Technology by Wang Huai

New Energy-efficient High-voltage
DC-DC Power Conversion Technology
Submitted to
Department of Electronic Engineering
電子工程學系
in Partial Fulfillment of the Requirements
for the Degree of Doctor of Philosophy
哲學博士學位
by
Wang Huai
王懷
March 2012
二零
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http://www.mediafire.com/?gwqda8k1hy9biy3

LOW-POWER PFC AND FORWARD CONVERTERS – METHODS TO IMPROVE PERFORMANCE Thesis for the degree of Doct or of Science in Technology

 

 

Helsinki University of Technology Institute

of Intelligent Power Electronics Publications

Espoo 2004 Publication 8

LOW-POWER PFC AND FORWARD CONVERTERS –

METHODS TO IMPROVE PERFORMANCE

Thesis for the degree of Doctor of Science in Technology

Vesa Tuomainen

Dissertation for the degree of Doctor of Science in Technology to be presented with due permission of

the Department of Electrical and Communications Engineering for public examination and debate in

Auditorium S4 at Helsinki University of Technology (Espoo, Finland) on the 4th of June, 2004, at 12

noon.

Helsinki University of Technology

Department of Electrical and Communications Engineering

Power Electronics Laboratory 

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http://www.mediafire.com/view/6346dis9hizi58i/LOWPOWERPFC.pdf 

FACTOR CORRECTION CONVERTERS FOR DISTRIBUTED POWER SYSTEM by MATADA MAHESH

FACTOR CORRECTION CONVERTERS FOR
DISTRIBUTED POWER SYSTEM

MATADA MAHESH
Dissertation submitted in partial fulfillment of the requirements for the
degree ofDoctor of Philosophy In Electrical Engineering
Under the supervision of
Prof. Anup Kumar Panda
Department of Electrical Engineering
National Institute of Technology, Rourkela
October 2011
ABSTRACT
In present situation, the increase in the utilization of computers, laptops,
uninterruptable power supplies, telecom and bio-medical equipments has become
uncontrollable as its growth is rising exponentially. Hence, increase in functionality of such
equipments leads to the higher power consumption and low power density which provided a
large market to distributed power systems (DPS). The development of these DPS posed
challenges to power engineers for an efficient power delivery with stringent regulating
standards; this is the motivation and driving force of this research work. The objective is to
minimize the switching losses of front-end converters employed in DPS, with the primary
aim of achieving nearly unity power factor operation of converters.
Single-phase and three-phase rectifiers are increasingly used in the field of alternating
current – direct current (AC-DC) power converters as front-end converters in DPS. For
power factor correction (PFC) stage, conventional single-phase AC-DC PFC boost converter
is the most suitable topology because of its inherent advantages. These PFC boost converters
exhibit poor dynamic regulation of output voltage owing to low pass filter in the voltage
feedback loop. Research effort has been made to mitigate this problem of AC-DC PFC boost
converters. An extended pulse width modulation switching technique has been investigated
and proposed especially for single-phase and three-phase AC-DC PFC boost converters to
improve the dynamic response of output voltage during transient periods.
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http://www.mediafire.com/?72t2phesuicz7mh