Fundamentals of Engineering Physics

MODULE DESCRIPTION

 

1)     MECHANICS

 

1.1.Generalities: Definition and introductory applications of mechanics; Physical quantities: scalar and vector quantities; Graphical representation of vectors; Types of vectors: unit, zero, collinear, equal and like vectors; Properties of vectors: addition, subtraction and multiplication with vectors

 

1.2.Statics: Force and Laws of forces: Parallelogram, triangle and polygon laws of forces, resolution of forces; Moment of a force; Couple of forces; Equilibrium of coplanar forces; Laws of friction: limiting and dynamic frictional forces, coefficients of friction and angle of friction

 

1.3.    Dynamics:

 

1.3.1.      Kinematics: Definitions of Distance, Displacement, Speed, Velocity, acceleration and their inter-related equations and graphs with respect to time change; Motion under gravity: free falling, vertical and oblique projections equations of motion with respect to the time change

 

1.3.2.      Kinetics: Newton`s laws: 1^st, 2^nd and 3^rd laws; Momentum, Work, Energy: Kinetic and Gravitation Potential energies, Conservative and Non-conservative forces, Work-Energy theorem; Power; Collisions: Elastic, Perfectly inelastic collisions; Rocket propulsion

 

1.3.3.      Circular motion: Angular speed and acceleration; Centripetal force; Conical Pendulum; Torque; Moment of inertial; Angular momentum and relation to torque, Conservation of angular momentum; Rotation kinetic energy; Work done by torque; Relation between circular and linear motions

 

2)     ELASTICITY

 

2.1.Elasticity of metals: Elastic properties of metals: Ductile and Brittle substances

 

2.2.Measurements of elasticity: Tensile stress; Tensile strain; Young`s modulus; Hooke`s law; Stress vs Strain graph: proportional limit, elastic limit, yield point, plastic deformation, Ultimate Tensile Stress, Breaking stress; Compression stress; Shearing stress; Force in bar due to contraction or expansion; Energy stored in a stretched wire; Graph of Force against extension and energy measurement; Energy per unit volume wire; longitudinal strain, lateral strain; Poison`s ratio

 

3)     FLUIDS

 

3.1.    STATIC FLUID: Hydrostatic pressure, Pascal` principle, Archimedes` principle

 

3.2.    FLUID DYNAMICS:

 

3.2.1.      Viscosity: Definition; Viscous properties of fluids, co-efficient of viscosity

3.2.2.      Laminar and turbulent flows: Definitions; Laminar flow in tubes; Poisseuille`s equation and its derivation; Turbulent flow in tubes

3.2.3.      Rate of flow or discharge of a fluid: Continuity equation

 

3.2.4.      Bernoulli`s equation: Bernoulli`s principle; Derivation of Bernoulli`s and Torricelli`s equations; Application of Bernoulli`s principle

 

 

 

 

 

4)     HEAT AND CALORIMENTRY

 

4.1.Generalities: Heat as energy transfer; Distinction between Temperature, Heat and Internal energy; Temperature scales: Degree Celsius, Kelvin and Degree Fahrenheit;

4.2.    Heat capacities

 

4.2.1.      Specific heat capacity: Definition; Measurements of specific heat capacity: method of mixtures, bomb calorimeter method and electric method

4.2.2.      Latent heat capacities: Distinction between latent heat of fusion and latent heat of vaporization

4.3.    Modes of heat transfer:

 

4.4.1.     Conduction: Definition; Working principle

 

4.4.2.     Convection: Definition, working principle

 

4.4.3.     Radiation: Definition, working principle

 

 

5)     GAS LAWS

 

5.1.    Ideal gas laws: Boyle`s law; Charles law; Kelvin`s law

 

5.2.Ideal gas equation: General gas equation, Avogadro`s hypothesis: Molar mass constant, Avogadro`s number

 

 

6)  THERMODYNAMICS

 

6.1. Thermodynamics laws: Zeroth, First and Second laws