DC circuits:
Ohm’s law and Kirchhoff’s laws, analysis of series, parallel and series-parallel circuitsexcited by independent voltage sources. Power and energy, maximum power transfer theorem appliedto the series circuit and its applications. Single-phase circuits: Generation of sinusoidal voltage, frequency of generated voltage, average value, RMS value, form, and peak factors. Voltage and current relationship, with phasor diagrams, in R, L, and C circuits.
Single-phase circuits (continued):
Analysis of R-L, R-C, R-L-C Series and Parallel circuits, Real power, reactive power, apparent power, and Power factor. Measurement of power.
Three-phase circuits:
Generation of three-phase power, representation of balanced star (3 wire and 4 wire system) and delta connected loads, the relation between phase and line values of voltage and current from phasor diagrams, advantages of three-phase systems. Measurement ofthree-phase powerby two-wattmeter method.
DC Machines:
(a) Principle of operation, constructional details, induced emf expression, types of generators, and the relation between induced emf and terminal voltage.
(b) Principle of operation, back emf and torque equations, types of motors, characteristics (shunt andseries only), and applications.
Transformers:
Necessity of transformer, the principle of operation, Types, and construction of single-phase transformers, emf equation, losses, variation of losses with respect to load, efficiency, and condition for maximum efficiency.
Three-phase induction Motors:
Concept of rotating magnetic field, Principle of operation, constructional features of motor, types – squirrel cage and wound rotor, slip and problems on the slip, significance of slip, applications.
Three-phase synchronous generators:
Principle of operation, constructional details of salient and non-salient pole generators, synchronous speed, frequency of generated voltage, emf equation, with the concept of winding factor (excluding the derivation and calculation of winding factors).
Power transmission and distribution:
Concept of power transmission and power distribution. Lowvoltage distribution system (400 V and 230 V) for domestic, commercial, and small-scale industry through block diagrams only.
Electricity bill:
Power rating of household appliances including air conditioners, PCs, laptops, printers,etc. Definition of “unit” used for consumption of electrical energy, two-part electricity tariff, calculation of electricity bill for domestic consumers.
Equipment Safety measures:
Working principle of Fuse and Miniature circuit breaker (MCB), merits and demerits.
Personal safety measures:
Electric Shock, Earthing and its types, Safety Precautions to avoid shock,and Residual Current Circuit Breaker (RCCB).
Course outcomes:
At the end of the course, the student will be able to
1) CO1: Analyse basic DC and AC electric circuits.
2) CO2: Explain the working principles of transformers and electrical machines.
3) CO3: Explain the concepts of electric power transmission and distribution of power.
4) CO4: Understand the wiring methods, electricity billing, and working principles of circuit protectivedevices and personal safety measures.
Assessment Details (both CIE and SEE)
The weightage of Continuous Internal Evaluation (CIE) is 50% and for Semester End Exam (SEE) is 50%. The minimum passing mark for the CIE is 40% of the maximum marks (20 marks). A student shall be deemed to have satisfied the academic requirements and earned the credits allotted to each subject/ course if the student secures not less than 35% ( 18 Marks out of 50)in the semester-end examination(SEE), and a minimum of 40% (40 marks out of 100) in the sum total of the CIE (Continuous Internal Evaluation) and SEE (Semester End Examination) taken together
Continuous Internal Evaluation:
Three Unit Tests each of 20 Marks (duration 01 hour)
1. First test at the end of 5th week of the semester
2. Second test at the end of the 10th week of the semester
3. Third test at the end of the 15th week of the semester
Two assignments each of 10 Marks
4. First assignment at the end of 4th week of the semester
5. Second assignment at the end of 9th week of the semester
Group discussion/Seminar/quiz any one of three suitably planned to attain the COs and POs for 20 Marks (duration 01 hours)
6. At the end of the 13th week of the semester
The sum of three tests, two assignments, and quiz/seminar/group discussion will be out of 100 marks and will be scaled down to 50 marks (to have less stressed CIE, the portion of the syllabus should not be common /repeated for any of the methods of the CIE. Each method of CIE should have a different syllabus portion of the course).
CIE methods /question paper is designed to attain the different levels of Bloom’s taxonomy as per the outcome defined for the course.
Semester End Examination:
Theory SEE will be conducted by University as per the scheduled timetable, with common question papers for the subject (duration 03 hours)
1. The question paper will have ten questions. Each question is set for 20 marks.
2. There will be 2 questions from each module. Each of the two questions under a module (with a maximum of 3 sub-questions), should have a mix of topics under that module.
The students have to answer 5 full questions, selecting one full question from each module.
Textbooks
1 Electrical and Electronic Technology Edward Hughes Pearson 12th edition, 2016
2 Basic Electrical Engineering D. C. Kulshreshtha McGraw-Hill Education 1st edition, 2019
3 A Textbook of Electrical Technology B.L.Theraja S Chand and Company Reprint Edition2014
Reference Books
1 Basic Electrical Engineering P.V. Prasad et al. Cengage 2019
2 Basic Electrical Engineering D.P. Kothari et al McGraw-Hill Education 4th Edition,2019
3 Principles Electrical Engineering and Electronics V.K Mehata, RohitMehta S Chand and Company 2nd edition, 2015