Phase 1 and Phase II These project are meant for use the knowledge acquired by the students during the coursework and should contribute to the needs of the society. These projects aims to provide an opportunity of designing and building complete system or subsystems in an area where the student like to acquire specialized skills. Maximum Number of Projects per academic year is 50 Numbers - Including Funded Projects. Selection Process will on first come first serve basis. We Guide projects in the following fields SCADA For Power Systems Automation Wind energy generation and storage system Computation of electric field distribution in a power apparatus. Controller design for grid tie inverter. Grid synchronisation in wind power harnessing. Analysing the needs and options of transmission for renewable energy Analysing Risk in Electricity Market Modelling the impact of electricity price tariffs and smart grids on customer demand Experimental setup of a Microgrid A power flow analysis model for microgrid A control scheme for grid connected wind energy generator Load frequency control of systems. Investigation of DFIG in a Microgrid Study on small signal stability of microgrids Developing techniques for transmission planning. Determination of efficiency of the Permanent Magnet Motors Modeling of wind turbine system for an Interior Permanent magnet generator Condition Monitoring of Power System Equipment Electrical insulation for high-voltage DC systems Congestion management in deregulated power system by optimal choice and allocation of FACTS controllers Dynamic Interaction of Power Plants and Power System in Deregulated Energy Markets ANALYSIS OF REAL POWER ALLOCATION FOR DEREGULATED POWER SYSTEM Analysis of stand – alone operation of single phase induction generator with energy storage system Optimal Relay coordination with Distributed generation Relay coordination with distributed generation Control of Double fed Induction Generator facing grid interruptions Stability improvement of a grid connected Wind energy system Study on grid connected wind driven induction generator under various fault conditions Energy optimized control of induction machines Voltage control of the parallel operated micro hydro synchronous generator and wind driven Induction generator with energy storage On-Line Tape Changing Power Transformer and reduced line voltage disturbance Design & Implementation of digital phase sequence indicator

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2. EXPERTSYSTEMSANDSOLUTIONS

3. 48, North Street, Aranarai, Perambalur, Tamil Nadu, India.
Email ID: expertsyssol@yahoo.com,
Website: www.researchprojects.info
Phone: 9952749533,
Energy conservation in industrial A.C drives
ABSTRACT
The induction motors can be considered the larger users of electrical energy. They are used both
in
industrial and commercial sectors in a wide range of applications, such as: fans, compressors,
pumps,
conveyor, winders, mills, transports, elevators, home appliances and office equipments. In India,
the electric
motors used in the industrial field consume typically the 60 to 70% of the total adsorbed
electrical energy.
In the commercial sector, this percentage is up to 35%.
With reference to industrial sector, a general purpose electrical motor consumes about an annual
quantity of electrical energy equal to 5 times its purchase costs and the motor live can he
evaluated around
10 to 12 years. On the base of these considerations, it is possible to obtain consistent energy
saving if higher
efficiency motors are used in the final applications.
World-wide, there exist several standards for testing electric machinery. For induction motors,
the
four most important are:
IEEE Standard 112-1996
IEC 34-2 and IEC 34-2A
JEC 37
IS 325
Several national standards are harmonized with regard to one of the three general standards
above.
The NEMA MG-1- 1993 standard and the Canadian standard C390 correspond to the IEEE
standard, while
in most of the European countries; the standards are harmonized to IEC 34-2. JEC stands for the
Japanese
standard. The efficiency value obtained from the considered testing standards can differ by
several percent,
as will be shown in the measurement results. Moreover, one standard can contain different
methods that do
not necessarily lead to one firmly determined value.

4. In this project, international standards are used to evaluate the efficiency of 3.7 KW, 4 pole
three-
phase induction motor and a logic based energy optimizer is developed using the numerical
values obtained
from the above standards.
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