DEPARTMENT OF ELECTRICAL ENGINEERING plan... · 2016-03-28 · 30 Lecture 30 EMF equation of ideal...

DEPARTMENT OF ELECTRICAL ENGINEERING

COLLEGE OF TECHNOLOGY AND ENGINEERING

MAHARANA PRATAP UNIVERSITY OF AGRICULTURE AND TECHNOLOGY, UDAIPUR

FIRST YEAR B.TECH. (I SEMESTER)

LECTURE PLAN

Course No.: EE 100

Course Name: ELECTRICAL ENGINEERING Cr. Hrs.4(3+1) Faculty: Guest Faculty

Recommended Books:

S.No. Title Author

1. Electrical Technology B. L. Therja

2. Network analysis M.E.Van Valkenberg

3. Introduction to Electrical Network Theory, Soni and Gupta.

4. Fundamentals of Electrical & Electronics. J.B. Gupta. (2002)

S.No. Lecture No. Topics and Contents

1. Lecture 1 D.C. Networks: Kirchoff’s law

2 Lecture 2 node voltage and mesh current methods

3 Lecture 3 delta-star transformation

4 Lecture 4 star delta transformation

5 Lecture 5 source conversion;

6 Lecture 6 solution of DC circuits by network theorems: Thevenin's,

7 Lecture 7 solution of DC circuits by network theorems: Norton’s

8 Lecture 8 Superposition theorem

9 Lecture 9 Reciprocity theorem

10 Lecture 10 Maximum Power Transfer theorem

11 Lecture 11 Single Phase A.C.Ciruits : Single Phase EMF generation

12 Lecture 12 average and effective values of sinusoidal wave forms

13 Lecture 13 average and effective values of linear periodic wave forms

14 Lecture 14 instantaneous and average power

15 Lecture 15 power factor

16 Lecture 16 reactive & apparent power

17 Lecture 17 solution of R-L-C circuits

18 Lecture 18 solution of series and parallel circuits

19 Lecture 19 solution of series-parallel circuits

20 Lecture 20 complex representation of impedances

21 Lecture 21 phasor diagram of series resonance

22 Lecture 22 phasor diagram of parallel resonance

23 Lecture 23 Three Phase A.C., Circuits : Three phase EMF generation

24 Lecture 24 delta and star-connection, line and phase quantities of three phase A.C.

circuits

25 Lecture 25 solution of the 3- phase balanced circuits

26 Lecture 26 Phasor diagram of the 3- phase balanced circuits

27 Lecture 27 measurement of power in three phase balanced circuits

28 Lecture 28 Transformer: Faraday's laws of Electromagnetic induction

29 Lecture 29 construction and principle operation of single phase transformer

30 Lecture 30 EMF equation of ideal transformer, voltage and current relationship

31 Lecture 31 voltage and current relationship of an ideal transformer

32 Lecture 32 Phasor diagram for ideal transformer

33 Lecture 33 Electrical Measuring Instruments : Introduction.

34 Lecture 34 type of measuring Instruments.

35 Lecture 35 Deflecting controlling & Damping Torque.

36 Lecture 36 D.C. PMMC instruments.

37 Lecture 37 shunts and multipliers, Moving iron ammeters and voltmeter.

38 Lecture 38 Dynamometers wattmeter, Induction type energy meter.




SECOND YEAR B.TECH. (IV SEMESTER)

LECTURE PLAN

Course No.: EE 221

Course Name: CIRCUIT THEORY – II Faculty: Dr. V. Dave

Recommended Books:

S.No. Title

Author

1. Electrical Circuit Analysis Soni & Gupta

2. Circuit Analysis & Synthesis Sudhakar


1. Lecture 1 Laplace transform and its application to network analysis

2 Lecture 2 transform networks and sources.

3 Lecture 3 initial and final value theorem

4 Lecture 4 inverse transform of initial and final value theorem.

5 Lecture 5 Unit impulse response.

6 Lecture 6 unit step response.

7 Lecture 7 the time shift theorem and convolution.

8 Lecture 8 Network functions and complex frequency plane- transfer functions.

9 Lecture 9 concepts of complex frequency

10 Lecture 10 poles and zero and restrictions on their location in s-plane.

11 Lecture 11 relation between natural transient frequencies and resonance

12 Lecture 12 Time domain behavior from pole-zero configuration,

13 Lecture 13 frequency response

14 Lecture 14 magnitude and phase of network functions .

15 Lecture 15 a relation between time domain analysis.

16 Lecture 16 a relation between frequency domain analysis

17 Lecture 17 Filters –two port reactance networks

18 Lecture 18 image impedance, attenuation,

19 Lecture 19 phase shift and insertion loss

20 Lecture 20 characteristics of constant –k and m-derived filters

21 Lecture 21 design of constant –k and m-derived filters

22 Lecture 22 Fourier integral and continous spectra

23 Lecture 23 the Fourier Integral spectrum analysis for recurring pulse

24 Lecture 24 relationship between fourier transform,

25 Lecture 25 relationship between and transform,

26 Lecture 26 analysis of circuit using fourier transforms

27 Lecture 27 sinusoidal transfer function.

28 Lecture 28 Network synthesis – the positive real concept

29 Lecture 29 brune ‘s positive realness

30 Lecture 30 properties of function , Hurwitz polynomials

31 Lecture 31 synthesis of two elements networks LC

32 Lecture 32 RC and networks, cauer and foster networks





LECTURE PLAN

Course No.: EE 222

Course Name: POWER SYSTEM – I Faculty: Dr. N. K. Jain

Recommended Books:

S.No. Title

Author

1. Power System Analysis & Design B.R Gupta

2. A course in Electrical power Soni Gupta and Bhatnagar


1. Lecture 1 Basics of power system; Insulators:

2 Lecture 2 Type of insulators and bushings

3 Lecture 3 voltage distribution over an insulator string.

4 Lecture 4 grading and methods of improving string efficiency.

5 Lecture 5 pollution flashover

6 Lecture 6 Corona: Electric stress between parallel conductor’s,

7 Lecture 7 Disruptive critical voltage

8 Lecture 8 visual critical voltage

9 Lecture 9 calculation for three phase overhead lines for corona power loss.

10 Lecture 10 factors effecting corona and effect of corona.

11 Lecture 11 Parameters of transmission lines:Basics

12 Lecture 12 Resistance of overhead transmission lines

13 Lecture 13 inductance of overhead lines

14 Lecture 14 capacitance of overhead lines

15 Lecture 15 effect of earth on capacitance,

16 Lecture 16 line transposition

17 Lecture 17 geometric mean radius and distance.

18 Lecture 18 calculation of inductance and capacitance of single phase transmission line.

19 Lecture 19 Skin and Proximity effect.

20 Lecture 20 Performance of transmission lines.

21 Lecture 21 Steady state analysis of short transmission line

22 Lecture 22 medium transmission lines

23 Lecture 23 long transmission lines

24 Lecture 24 Generalized ABCD line constants

25 Lecture 25 receiving end power circle diagrams

26 Lecture 26 sending end power circle diagrams

27 Lecture 27 Ferranti effect

28 Lecture 28 interference with communication circuits

29 Lecture 29 Underground cables: Type of cables

30 Lecture 30 insulation resistance calculation of Underground cables.

31 Lecture 31 capacitance calculation of Underground cables.

32 Lecture 32 reduction of maximum stresses.

33 Lecture 33 causes of breakdown .

34 Lecture 34 idea about oil and gas filled cables.

35 Lecture 35 typical cases of line terminations .





LECTURE PLAN

Course No.: EE 223

Course Name: ELECTRICAL MACHINES – I Faculty: Dr. Jai Kumar Meherchandani

Recommended Books:

S.No. Title

Author

1. Fundamentals of Electric Machines B.R. Gupta & Vandana Singhal

2. Electric Machines (Second Edition) I.J. Nagrath & D.P. Kothari

3. Electrical Machines P.K.Mukherjee & S.Chakravorti


1. Lecture 1 Transformers: Constructional features.

2 Lecture 2 emf equation and phasor diagram of transformer

3 Lecture 3 equivalent circuits of transformer

4 Lecture 4 open circuit and short circuit test of transformer

5 Lecture 5 Sumpner’s test of transformer

6 Lecture 6 efficiency, and voltage regulation of transformer

7 Lecture 7 all-day efficiency of transformer

8 Lecture 8 separation of losses of transformer

9 Lecture 9 parallel operation and autotransformers.

10 Lecture 10 Polyphase Transformers: standard connections for three-phase operation

and single phasing .

11 Lecture 11 unbalanced load conditions on a threephase transformer.

12 Lecture 12 Scott connection of Polyphase Transformers.

13 Lecture 13 six-phase transformation.

14 Lecture 14 Electromechanical Energy Conversion: Basic principles of

electromechanical energy conversion, energy balance.

15 Lecture 15 basic principles of operation of electric generators and motors

16 Lecture 16 DC Machines: Fundamentals of DC machine,

17 Lecture 17 Construction and armature windings of DC machine

18 Lecture 18 simple lap and wave windings, chording, equalizing connections.

19 Lecture 19 DC Generators: EMF equation.

20 Lecture 20 Types of DC generators, no load and load characteristics.

21 Lecture 21 parallel operation of DC Generators.

22 Lecture 22 Armature Reaction: Distribution of armature and field mmfs.

23 Lecture 23 Commutation: Introduction to commutation and reactance voltage.

24 Lecture 24 resistance commutation and interpoles.

25 Lecture 25 DC Motors: Principle of operation.

26 Lecture 26 production of torque and back emf of DC Motors.

27 Lecture 27 torque-current and torque-speed characteristics of motors.

28 Lecture 28 starting of motors and speed control by variation of armature voltage.

29 Lecture 29 speed control by field current and Ward Leonard method

30 Lecture 30 electric braking, losses and efficiency

31 Lecture 31 direct and indirect tests, Swinburne’s test of motors.

32 Lecture 32 Hopkinson’s test and field test.

33 Lecture 33 retardation test of motors and Rosenberg generator.

34 Lecture 34 Cross-Field Machines: Basic principles of operation of metadyne.

35 Lecture 35 amplidyne and their applications.




THIRD YEAR B.TECH. (VI SEMESTER)

LECTURE PLAN

Course No.: EE 321

Course Name: ELECTROMAGNETIC & FIELD THEORY Faculty: Dr. Naveen Jain

Recommended Books:

S.No. Title Author

1. Engineering Electromagnetics Hayt Jr, William.

2. Electromagnetics with application Kraus, Fleish.

3. Introduction to Electromagnetics Griffith David J.


1. Lecture 1 Vector relation in rectangular and cylindrical coordinate system.

2 Lecture 2 Vector relation in spherical coordinate system .

3 Lecture 3 Vector relation in general curvilinear coordinate system .

4 Lecture 4 surface & volume integral; Concept and physical interpretation of: Gradient.

5 Lecture 5 Concept and physical interpretation of: Divergence and Curl.

6 Lecture 6 Stokes Theorem and Helmholtz Theorem.

7 Lecture 7 Electrostatics: Introduction to Electric field vectors.

8 Lecture 8 Electric field due to charge configuration.

9 Lecture 9 Potential function and displacement ratio.

10 Lecture 10 Gauss law, Poison’s and Laplace’s equation’s.

11 Lecture 11 Uniqueness theorem and continuity equation.

12 Lecture 12 Capacitance & electrostatic energy.

13 Lecture 13 Field determination by method of image.

14 Lecture 14 Boundary condition and Field mapping .

15 Lecture 15 Concept of field cell.

16 Lecture 16 Magneto-statics: Introduction to magnetic field vectors.

17 Lecture 17 Bio-Savart and Ampere’s law.

18 Lecture 18 Magnetic scalar and vector potential.

19 Lecture 19 Self and mutual inductance energy stored in magnetic field.

20 Lecture 20 Boundary condition.

21 Lecture 21 , Analogy between electric and magnetic field.

22 Lecture 22 Field mapping and concept of field cell.

23 Lecture 23 Time-Varying Fields: Faraday’s law.

24 Lecture 24 Displacement current & equation of continuity.

25 Lecture 25 Maxwell’s equation.

26 Lecture 26 UPW: Free space, dielectrics and conductors.

27 Lecture 27 Skin effect and sinusoidal time variation.

28 Lecture 28 Reflection, refraction and polarization of UPW standing wave ratio.

29 Lecture 29 Pointing vector and power consideration.

30 Lecture 30 Radiation and Transmission, Retarded potential and concepts of radiation.

31 Lecture 31 , radiation from small current elements.

32 Lecture 32 Transmission line parameters.

33 Lecture 33 Introduction to EMI & EMC.

34 Lecture 34 EMI coupling nodes, methods of eliminating interference.

35 Lecture 35 shielding, grounding, conducted EMI.

36 Lecture 36 EMI testing, emission testing, susceptibility testing.





LECTURE PLAN

Course No.: EE 322

Course Name: POWER ELECTRONICS – II Faculty: Dr. Vinod K. Yadav

Recommended Books:

S.No. Title Author

1. Power Electronics P.S. Bimbhra

2. Power Electronics Berde

3. Power Electronics.

P.C. Sen


1. Lecture 1 Converters: Performance measures of single phase converter.

2 Lecture 2 Performance measures of three-phase converters.

3 Lecture 3 discontinuous conduction in two quadrant converters.

4 Lecture 4 power factor improvements.

5 Lecture 5 Extinction angle control.

6 Lecture 6 symmetrical angle control .

7 Lecture 7 pulse width modulation control.

8 Lecture 8 sinusoidal pulse width modulation control.

9 Lecture 9 Thyristor commutation scheme- Line commutation.

10 Lecture 10 load commutation.

11 Lecture 11 forced and external pulse commutation.

12 Lecture 12 Cycloconverter: Basic principle of operation .

13 Lecture 13 single phase to single phase output equation of cycloconverters.

14 Lecture 14 Choppers: Principle of chopper operation,

15 Lecture 15 control strategies for choppers.

16 Lecture 16 step-up chopper and reversible chopper.

17 Lecture 17 Steady state time domain analysis of type-A chopper.

18 Lecture 18 Chopper configuration and chopper commutation.

19 Lecture 19 AC Chopper and Multiphase chopper.

20 Lecture 20 Inverters: Inverter classification.

21 Lecture 21 Voltage source thyristor inverters.

22 Lecture 22 single phase half bridge inverters with auxiliary communication .

23 Lecture 23 single phase full bridge inverters with auxiliary communication.

24 Lecture 24 single phase half and full bridge inverters with complementary communication.

25 Lecture 25 Three phase bridge inverters with 180 mode .

26 Lecture 26 Three phase bridge inverters with 120 mode.

27 Lecture 27 Pulse width modulation inverters.

28 Lecture 28 Current source inverters.

29 Lecture 29 single phase capacitor-commutated CSI with restive load.

30 Lecture 30 single phase auto-sequential commutated inverter.

31 Lecture 31 three phase auto-sequential commutated inverter.

32 Lecture 32 single phase series inverters & parallel or push pull inverters.

33 Lecture 33 Voltage control of inverters .





LECTURE PLAN

Course No.: EE 323

Course Name: INSTRUMENTATION Faculty: Dr. Jai Kumar

Recommended Books:

S.No. Title Author

1. Electrical Measurement & Instrumentation A.K. Shawney

2. Electronic Instrumentation Kalsi

3. Electronic Instrumentation Albert Cooper


1. Lecture 1 Theory of errors: Accuracy and precision.

2 Lecture 2 systematic and random errors.

3 Lecture 3 limits of errors.

4 Lecture 4 probable errors and standard deviation.

5 Lecture 5 Gaussian error curves.

6 Lecture 6 Combinational errors.

7 Lecture 7 Transducers: Constructional features, operating characteristics and selection.

Criteria of active, passive and digital transducers,

8 Lecture 8 Constructional features and operating characteristics of Transducers.

9 Lecture 9 Selection Criteria of active, passive transducers.

10 Lecture 10 Selection Criteria of digital transducers.

11 Lecture 11 block diagram representation for the instrumentation of strain.

12 Lecture 12 block diagram representation for the instrumentation of displacement and

velocity

13 Lecture 13 Acceleration and force measurement.

14 Lecture 14 torque, flow, pressure and temperature.

15 Lecture 15 Signal conditioning: a.c. & d.c. Bridges

16 Lecture 16 analysis of unbalanced bridges,

17 Lecture 17 Instrumentation amplifier and operational amplifiers.

18 Lecture 18 choppers, established and carrier amplifiers

19 Lecture 19 charge amplifiers, A/D & D/A converters.

20 Lecture 20 Phase sensitive detectors, shielding and grounding.

21 Lecture 21 Signal recovery: Signal filtering, averaging, correlation and coding.

22 Lecture 22 Signal transmission and telemetry.

23 Lecture 23 Modulation and encoding methods,

24 Lecture 24 transmission media, Time division multiplexing.

25 Lecture 25 frequency multiplexing.

26 Lecture 26 Signal recording and display- Analog and digital display, Recorders.

27 Lecture 27 storage oscilloscopes, printers and plotters.

28 Lecture 28 Data acquisition system (analog and digital).





LECTURE PLAN

Course No.: EE 325

Course Name: ELECTRICAL ENGINEERING MATERIALS Faculty: Mr. vahid hussain

Recommended Books:

S.No. Title Author

1. An introduction to Electrical Engineering Materials, C.S Indulkar & S. Thriuvengadam

2. A course in Electrical Engineering Materials, S.P.Seth & P.V.Gupta

3. Electrical Engineering Materials B.D.Indu


1. Lecture 1 Conductor Materials: Electrical, thermal properties of conductive and

resistive material

2 Lecture 2 Mechanical properties of conductive and resistive material

3 Lecture 3 Important characteristics and applications of specific conductor materials like

copper, aluminium


AAC, ACSR


silver, gold, platinum and tungsten,

6 Lecture 6 Study of important resistance materials, carbon and nicrome

7 Lecture 7 Study of important standard resistance materials.

8 Lecture 8 Soldering alloys.

9 Lecture 9 Super-conducting Materials: Introduction, critical field and critical current

density, ,

10 Lecture 10 Type I and type II superconductors

11 Lecture 11 Intermediate state, penetration depth and thin films

12 Lecture 12 Superconductivity at high frequencies

13 Lecture 13 Application of superconductivity

14 Lecture 14 Advancements in super conducting materials

15 Lecture 15 Dielectric materials: Dielectric behavior of materials under static and

dynamic field

16 Lecture 16 Polarisation, induced and permanent dipole moments,

17 Lecture 17 Surface resistivity. Breakdown processes.

18 Lecture 18 Thermal properties Electrical properties of important dielectric materials

including plastics and ceramics

19 Lecture 19 Ferroelectric and piezo-electric materials.

20 Lecture 20 Magnetic Materials: characteristics of diamagnetic,

21 Lecture 21 Paramagnetic, ferromagnetic

22 Lecture 22 Ferrimagnetic and anti-ferromagnetic materials,

23 Lecture 23 Properties and applications of common nonretentive and retentive magnetic

materials including various alloys,.

24 Lecture 24 Ferrites and powder cores

25 Lecture 25 Eddy current and hysteresis losses, Curie point

26 Lecture 26 Semiconductor materials: Electric properties of semiconducting elements

27 Lecture 27 Compounds and their application.

28 Lecture 28 Zone refining and crystal growth

29 Lecture 29 Miscellaneous materials: important electronic properties of electron emitting

materials,

30 Lecture 30

Photosensitive materials and luminescent materials.

31 Lecture 31 .




FOURTH YEAR B.TECH. (VIII SEMESTER)

LECTURE PLAN

Course No.: EE 421

Course Name: ADVANCED POWER SYSTEMS Faculty: Mr. Anshul Kumawat

Recommended Books:

S.No. Title

Author

1. Power system analysis J J Grainger and W D Stevenson

2. Flexible AC transmission systems K. R. Padiyar

3. Power system analysis Wooden Woollen Berg


1. Lecture 1 EHV AC Transmission: Need of EHV transmission lines,

2 Lecture 2 power handling capacity and surge impedance loading.

3 Lecture 3 Problems of EHV transmission,

4 Lecture 4 bundled conductors geometric mean radius of bundle,

5 Lecture 5 properties of bundle conductors

6 Lecture 6 Electrostatic fields of EHV lines and their effects,

7 Lecture 7 corona effects: Corona loss, audio and radio noise

8 Lecture 8 HVDC Transmission: Types of D.C. links, ,

9 Lecture 9 advantages and disadvantages of HVDC transmission

10 Lecture 10 Basic scheme and equipment of converter station.

11 Lecture 11 Analysis of HVDC Converters, twelve-pulse converter

12 Lecture 12 Ground return. Basic principles of DC link control

13 Lecture 13 basic converter control characteristics, s

14 Lecture 14 ystem control hierarchy, various controls of HVDC like VDCOL,

15 Lecture 15 firing angle control, current and extinction angle control

16 Lecture 16 gamma controller, power controller.

17 Lecture 17 Introduction to multi-terminal DC systems, ,

18 Lecture 18 application of MTDC Systems, types of MTDC systems

19 Lecture 19 Control and protection of MTDC systems.

20 Lecture 20 Description of various converters and inverters circuits,

21 Lecture 21 HVDC circuit breakers, Harmonics and filters,

22 Lecture 22 Measurement of HVDC quantities

23 Lecture 23 Reactive power requirements and sources of reactive power.

24 Lecture 24 Converter Faults and.

25 Lecture 25 protection against over currents, over voltages

26 Lecture 26 FACTS: Problems of AC transmission lines.

27 Lecture 27 Phenomena of voltage collapse,.

28 Lecture 28 basic theory of line compensation

29 Lecture 29 Basic features of FACTS controllers

30 Lecture 30 Basic schemes and operations of thyristor controlled

31 Lecture 31 series compensator phase angle regulator, dynamic brake

32 Lecture 32 Introduction to static synchronous compensator (STATCOM) and

33 Lecture 33 unified power flow controller (UPFC).




FOURTH YEAR B.TECH. (VIII SEMESTER)

LECTURE PLAN

Course No.: EE 422

Course Name: NEURAL AND FUZZY BASED CONTROL SYSTEM Faculty: Dr. R.R. Joshi

Recommended Books:

S.No. Title

Author

1. Introduction of artificial neural systems J.M. Zurada. (1997).

2. Neural networks S. Iiaykin. (1994).

3. Neuro control and its application S. Omatu, M. Khalid, R. Yusof. (1996).


1. Lecture 1 Artificial neural systems : Preliminaries, ,

2 Lecture 2 fundamental concepts & models of artificicalsystem, neural networks

learning rules

3 Lecture 3 Hebbian, perceptron,

4 Lecture 4 delta Widrow-Hoff learning rules

5 Lecture 5 Single layer percepton classification : Classification model, features &

decision regions training &,

6 Lecture 6 classification using discrete perception

7 Lecture 7 algorithm & examples

8 Lecture 8 single layer continuous perceptron networks for linear separable classification

9 Lecture 9 Multilayer feedback work networks Generalized delta learning rule

10 Lecture 10 feedforword recall & error back propagation training, learning factors.

11 Lecture 11 Single layer feedback networks : basic concepts of dynamical systems

mathematical modeling of discrete time &

12 Lecture 12 gradient type Hopfield networks

13 Lecture 13 Neural network in control system : Neuro-control approaches,

14 Lecture 14 training algorithm evaluation of training algorithms, through simulation,

15 Lecture 15 self tuning neuro-control scheme,

16 Lecture 16 self tuning PID neural controller

17 Lecture 17 neuro-control scheme feed water bath temperature control system.

18 Lecture 18 Mathematical of fuzzy control: fuzzy sets, fuzzy set theory, .

19 Lecture 19 properties of fuzzy sets

20 Lecture 20 Operations of fuzzy sets, fuzzy relations

21 Lecture 21 Non linear fuzzy control: The control problem,

22 Lecture 22 FKBC as non linear transfer element PID

23 Lecture 23 sliding mode type FKBC

24 Lecture 24 some typical application of fuzzy based control systems.

25 Lecture 25 Adaptive Fuzzy control: Introduction, design &,

26 Lecture 26 performance evaluation, performance monitor

27 Lecture 27 main approaches to design

28 Lecture 28 Stability of fuzzy control system: state space approach,

29 Lecture 29 stability and robustness indices

30 Lecture 30 input-output stability

31 Lecture 31 FKBC design parameters: Structure of FKBC fuzzification and,

32 Lecture 32 defuzzification module

33 Lecture 33 rule based choice of variable

34 Lecture 34 contents of rules, derivation of rule data based,.

35 Lecture 35 choice of membership function and scaling factors




FOURTH YEAR B.TECH. (VIII SEMESTER) ELECTIVE – I

LECTURE PLAN

Course No.: EE 423(a)

Course Name: UTILIZATION OF ELECTRICAL POWER Faculty: Ms. Himani Paliwal

Recommended Books:

S.No. Title

Author

1. Utilisation of Electrical Power H. Pratap

2. Electrical power systems Soni, Gupta, Bhatnagar


1. Lecture 1 Electric drives- Characteristics of load,

2 Lecture 2 Characteristic of different drives, size and rating of electric drives

3 Lecture 3 Load equalization and flywheel, ,

4 Lecture 4 Selection of electric drives for specific application

5 Lecture 5 Electric braking

6 Lecture 6 Behavior of motor during starting,.

7 Lecture 7 Acceleration braking & reversing operation

8 Lecture 8 Different methods of electric heating, Arc furnace & induction furnace

9 Lecture 9 Principle of high frequency induction and

10 Lecture 10 Dielectric heating

11 Lecture 11 Principles of illumination,

12 Lecture 12 Electric light sources,

13 Lecture 13 Designing scheme for commercial,

14 Lecture 14 Industrial street & flood lighting

15 Lecture 15 Systems of electric traction, track electrification, ,

16 Lecture 16 Means of supplying power & train lighting

17 Lecture 17 Substation equipment & layout, over head equipment

18 Lecture 18 D.C. & A.C. traction motor,

19 Lecture 19 Various method of starting

20 Lecture 20 Speed control

21 Lecture 21 Metadyne control series-parallel starting methods of electric braking of

traction motor speed-time curve,

22 Lecture 22 Metadyne control series-parallel starting methods of electric braking of

traction motor speed-time curve,

23 Lecture 23 Tractive efforts specific energy conversion

24 Lecture 24 Mechanics of train movement




FOURTH YEAR B.TECH. (VIII SEMESTER) ELECTIVE – II

LECTURE PLAN

Course No.: EE 424(b)

Course Name: HIGH VOLTAGE ENGINEERING Faculty: Ms. Kusumlata

Recommended Books:

S.No. Title

Author

1. High voltage engineering K. Naidu

2. High voltage engineering C.L.Wadhwa


1. Lecture 1 Mechanism of breakdown in gases, liquids and solids

2 Lecture 2 Townsands

3 Lecture 3 Streamer theories, Paschin’s law

4 Lecture 4 Impulse generator circuit

5 Lecture 5 Techniques to observe wave front on CRO

6 Lecture 6 Method of generation of power frequency high voltages- and

7 Lecture 7 Cascade transformers

8 Lecture 8 Resonance methods

9 Lecture 9 Generation of H.V.D.C. voltage stabilization,

10 Lecture 10 Tesla coil.

11 Lecture 11 Measurements of high voltage: Potential divider, sphere gap and

12 Lecture 12 Electrostatic voltmeter, oscilloscope

13 Lecture 13 Measurements of high voltage: Potential divider, sphere gap, and

14 Lecture 14 Electrostatic voltmeter, oscilloscope

15 Lecture 15 Their application in high voltage measurements and

16 Lecture 16 Measurement of loss angle

17 Lecture 17 Partial discharge measurement techniques

18 Lecture 18 H.V. testing: Wet and dry flash over test

19 Lecture 19 Testing of insulators in simulated pollution conditions.

20 Lecture 20 Accumulation of charges in clouds,

21 Lecture 21 Direct and indirect strokes

22 Lecture 22 Isokeravnic level

23 Lecture 23 Switching surges, protection of system against surges

DEPARTMENT OF ELECTRICAL ENGINEERING plan... · 2016-03-28 · 30 Lecture 30 EMF equation of ideal...

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