Course –Handout
Exercises Proposed for teaching EEE 403 Power Syatem – I
1. Name of the Teacher
P. D. Kashyap
2. Department
Electrical Engineering
3. Course Title
Power System - I
4. Course code
EE 403
5. Credit Value:
4 [P=2, T=0, L=3]
6. Objectives of the course:
The course is designed to introduce the Electrical Power system:
i)
ii)
iii)
Introduction to Generation, Transmission and Distribution of
Power System, types and operations, modelling of overhead
transmission lines.
Study of modern FACTS Devices, their performance and
operation.
Introduction to EHV/HVDC new technology transmission systems.
7. Learning Outcomes:
Students successfully completing this module will be able to:
i) understand the different types of electrical power generating plants,
their performance and maintenance. Site selection, different type of
equipments used in generating plants. Generation, Transmission and
Distribution,
ii) They will be able to understand the fundamental parameters of a
transmission system and will have an idea to model the power
systems, fault calculations, repairing and maintenance works
iii) They will get the basic information of power system operation and
control, and with new transmission technologies of HVDC and
communication techniques like SCADA.
8. Subject Matter:
Unit
I
II
III
IV
Topics
Number of
Lectures
Generation of Electric Power: Brief description of 12
Thermal, hydro nuclear and gas power plants & other
non- conventional power plants.
Legal aspects of electricity supply- Electricity acts,
rules and codes. Standards followed in power supply,
environmental and safety measures, Factors influencing
tariffs, types of consumers, different types of tariffs.
Calculation of line parameters with symmetrical and
unsymmetrical spacings.
Transmission and Distribution Systems: DC 2–wire 12
and 3–wire systems, AC single phase, three phase and
4-wire systems, and comparison of copper efficiency.
Distribution Systems: primary and secondary
distribution systems, concentrated & uniformly
distributed loads on distributors one and both ends,
ring distribution, sub mains and tapered mains, voltage
drop and power loss calculations, voltage regulators.
Overhead Line Insulators and Mechanical Design of 12
Transmission Lines: Type, string efficiency, voltage
distribution in string of suspended insulators, grading
ring, preventive maintenance.
Different types of
tower, sag- tension calculations, sag-template, string
charts, vibrations & damaging Corona-losses, radio &
audio noise, transmission line–communication line
interference.
Introduction to EHV/HVDC transmission: Brief
description of both the systems with working &
constructional details.
Overhead Transmission Lines and Cables: Types of 12
Conductors, Line parameters; calculation of inductance
and capacitance of single and double circuit
transmission lines, three phase lines with stranded and
bundle conductors, Generalized ABCD constants and
equivalent circuits of short, medium & long lines. Line
Performance: regulation and efficiency of short,
medium and long lines, Series and shunt
compensation, Introduction to FACTS. Calculations of
capacity of cables, charging current, stress, grading,
heating of cables, Construction and characteristics of
HV & EHV cable.
A. Teaching/Learning/Practice Pattern
Teaching: 50%
Learning: 10%
Practice : 40%
(Industrial expert will be invited to deliver talks)
B. Examination Pattern
Theoretical Examination : Written
Practical Examination: Conducting experiments and viva-voce.
C. Practical list
1.
Introduction to TLS(Transmission Line Simulator) and its
components
2.
To demonstrate the PU calculation a converting the given
transmission line data on to given MVA base.
3.
To compute PU values computation of the transmission line
simulator values for the given line.
4.
To verify the Ferranti effect simulation for an un-loaded
transmission line.
5.
To determine the surge impedance of the given transmission
line.
6.
To determine the loading capability of the line and voltage
regulation at given power factor.
7.
8.
D. Books
1.
2.
3.
4.
5.
6.
7.
8.
To determine the shunt capacitive compensation to improve the
receiving end voltage and power factor.
To determine the operating time of the over current relay.
Olle I. Elgard, “Electric Energy Systems Theory, An
Introduction” 2nd Edition, McGraw Hill Education (India) Pvt.
Ltd.
Grainger John, J. and Stevenson, Jr. W.D., “Power System
Analysis”, McGraw Hill, 1994.
Harder Edwin.I, “Fundamentals of Energy Production”, John
Wiley and Sons, 1982.
Deshpande, M.V., “Elements of Electric Power Station
Design”, A.H. Wheeler and Company, Ald 1979.
BurkeJames,J., “PowerDistribution Engineering;
Wadhwa, C.L.,“Electric Power Systems”, Second Edition,
Wiley EasternLimited,1985. Fundamentalsand Applications”
Marcel Dekk., 1996.
Nagrath,I.J. and Kothari, D.P., “Power System Engineering”,
Tata McGraw Hill, 1995.
“Electric Transmission and Distribution Reference Book”,
Westing house Electric Corporation: East Pittsburg, Pa, 1964.
E. Magazines:
1.
Electricity Today, T & D Magazine.
2.
Electrical Line, Line Magazines.
3.
Electrical India Magazine, (Online Magazine)
4.
Power and Energy Magazine, IEEE.
F. Journals:
1.
Power Apparatus and Systems, IEEE Transactions.
2.
.Power Delivery, IEEE Transactions.
3.
Power Engineer Magazine, IET.
4.
Electrical Power, Elsevier.
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