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Unit 1
- 1. 20EEG01 - BASIC ELECTRICAL AND ELECTRONICS ENGINEERING By R.Kanmani, AP(Sr.Gr)/ECE SRIT
- 2. Course Objective The course aims to provide the basic principles of electric circuits, electron devices, electrical wiring and AC/DC machines for applications in real time engineering problems.
- 3. Course Content Electric circuits and Domestic Wiring Ohm’s Law and Kirchhoff’s laws - series and parallel circuits, equivalent resistance- Mesh and Nodal Analysis (Analysis with only independent source and DC circuits)- Superposition theorem, Thevenin’s theorem, Norton’s theorem. Types of wiring- Domestic wiring - Specification of Wires – Importance of Earthing. AC Circuits Concepts of AC circuits –RMS value, average value, form and peak factors. Power relations in single phase and three phase circuits- real and reactive power – power factor, Star connection – Delta connection –Balanced Loads.
- 4. Course Content Electrical Machines Construction, Principle of operation and characteristics of DC separately excited generator and DC Shunt and Series motor, EMF equation of DC separately excited generator and Torque equation of DC Shunt and Series motor- applications. Construction and Principle of operation of transformer, EMF Equation- applications. Construction and Principle of operation of synchronous Motor. Construction and Principle of operation of single phase Induction motor - applications. Semiconductor Devices and Applications Introduction to semiconductors- PN junction diode - forward and reverse bias characteristics –Zener diode and its characteristics. Operation of Half wave and Full wave rectifiers – Capacitive filters- Zener diode Voltage regulators
- 5. Course Content Current Controlled Devices Operation of PNP and NPN transistors - Early effect – Input and Output Characteristics of CB, CE, CC Configurations , Working principle and characteristics of SCR, UJT.
- 6. References 1. A Fitzgerald , Charles Kingsley , Stephen Umans, “Electric Machinery”, 7th Edition, McGraw-Hill, 2013. 2. Robert Boylestad, Louis Nashelsky, “Electronic Devices and Circuit Theory”, Prentice Hall, 11th Edition 2015. 3. V K Mehta, Rohit Mehta , “ Principles of Electronics”, 11 th edition, S Chand Publishing company , 2016. 4. Mahmood Nahvi, Joseph A Edminister, “Electric Circuits”, McGraw-Hill Education, 5th Edition, 2010. 5. Bhattacharya.S.K, “Basic Electrical and Electronics Engineering”, 1st Edition, Pearson Education, 2011
- 7. Course Outcomes CO1: Ability to understand the basic concepts of electric circuits, electronic devices &circuits and electric machines CO2: Ability to understand the concepts related with electrical domestic wiring CO3: Ability to apply the concepts of electrical machines for industrial applications CO4: Ability to analyze the characteristics of electronic devices and circuits
- 8. Ohm’s Law Ohm’s law states that the voltage or potential difference between two points is directly proportional to the current or electricity passing through the resistance, and directly proportional to the resistance of the circuit. The formula for Ohm’s law is V=IR. This relationship between current, voltage, and relationship was discovered by German scientist Georg Simon Ohm.
- 10. Most basic components of electricity are voltage, current, and resistance. Ohm’s law shows a simple relation between these three quantities. Ohm’s law states that the current through a conductor between two points is directly proportional to the voltage across the two points.
- 11. Ohm’s Law Formula Voltage= Current× Resistance V= I×R V= voltage, I= current and R= resistance The SI unit of resistance is ohms and is denoted by Ω This law is one of the most basic laws of electricity. It helps to calculate the power, efficiency, current, voltage, and resistance of an element of an electrical circuit.
- 12. Limitations of Ohm’s Law Ohm’s law is not applicable to unilateral networks. Unilateral networks allow the current to flow in one direction. Such types of network consist elements like a diode, transistor, etc. Ohm’s law is also not applicable to non – linear elements. Non-linear elements are those which do not have current exactly proportional to the applied voltage that means the resistance value of those elements changes for different values of voltage and current. Examples of non – linear elements are the thyristor.
- 13. Uses of Ohm’s Law The basic quantities of electricity are the current, voltage and resistance. Ohm’s Law establishes a simple equation between the three quantities, serving as the most basic law of electricity. Ohm’s law helps in calculating the power, efficiency and the impedance of any element of the electrical circuit. It helps in determining the voltage, current or resistance of a linear circuit when either of the two quantities is known.
- 14. Kirchhoff’s First Law – The Current Law, (KCL) Kirchhoff’s Current Law or KCL, states that the “total current or charge entering a junction or node is exactly equal to the charge leaving the node as it has no other place to go except to leave, as no charge is lost within the node“. In other words the algebraic sum of ALL the currents entering and leaving a node must be equal to zero, I(exiting) + I(entering) = 0. This idea by Kirchhoff is commonly known as the Conservation of Charge.
- 15. We can use Kirchhoff’s current law when analyzing parallel circuits.
- 16. Kirchhoff’s Second Law – The Voltage Law, (KVL) Kirchhoff’s Voltage Law or KVL, states that “in any closed loop network, the total voltage around the loop is equal to the sum of all the voltage drops within the same loop” which is also equal to zero. In other words the algebraic sum of all voltages within the loop must be equal to zero. This idea by Kirchhoff is known as the Conservation of Energy.
- 17. Starting at any point in the loop continue in the same direction noting the direction of all the voltage drops, either positive or negative, and returning back to the same starting point. It is important to maintain the same direction either clockwise or anti-clockwise or the final voltage sum will not be equal to zero. We can use Kirchhoff’s voltage law when analyzing series circuits.
- 18. Common circuit theory terms Circuit – a circuit is a closed loop conducting path in which an electrical current flows. Path – a single line of connecting elements or sources. Node – a node is a junction, connection or terminal within a circuit were two or more circuit elements are connected or joined together giving a connection point between two or more branches. A node is indicated by a dot. Branch – a branch is a single or group of components such as resistors or a source which are connected between two nodes. Loop – a loop is a simple closed path in a circuit in which no circuit element or node is encountered more than once. Mesh – a mesh is a single closed loop series path that does not contain any other paths. There are no loops inside a mesh.