Mechanical Engineering Preparation

Mechanical Engineering Preparation

About Course

This Refresher Course helps aspiring candidates to recapitulate and improve their fundamental knowledge on various subjects pertaining to Mechanical Engineering.

It covers the relevant topics under the academic curriculum for Graduate and Diploma level Engineering, where video lectures from world class institutions e.g. IITs, IISc etc. have been facilitated for dissemination of knowledge.

What Will You Learn?

  • Applied Mechanics and Design
  • Fluid Mechanics and Thermal Sciences
  • Materials, Manufacturing and Industrial Engineering

Course Content

Engineering Mechanics

  • Introduction to Vectors
    15:39
  • Addition and subtraction of vectors
    13:56
  • Multiplying vectors
    11:32
  • Introduction to vectors: solved examples I
    38:32
  • Introduction to vectors: solved examples II
    19:54
  • Transformation of vectors under rotation
    22:54
  • Vector products and their geometric interpretation
    16:38
  • Vector Product: Kronecker Delta and Levi-Civita symbols-I
    15:50
  • Vector Product: Kronecker Delta and Levi-Civita symbols-II
    14:11
  • Equilibrium of rigid bodies – Forces and torques
    20:59
  • Calculating torques and couple moments – I
    19:31
  • Calculating torques and couple moments – II
    16:52
  • Finding a force and a couple equivalent to an applied force
    11:20
  • Different elements and associated forces and torques – I
    12:29
  • Different elements and associated forces and torques – II
    15:56
  • Solved examples; equilibrium of bodies – I
    22:55
  • Solved examples; equilibrium of bodies – II
    14:59
  • Forces in different geometric configurations
    17:09
  • Plane trusses I – Building a truss and condition for it to be statically determinate
    22:16
  • Plane trusses II – Calculating forces in a simple truss and different types of trusses
    19:41
  • Plane trusses III – Calculating forces in a simple truss by method of joints
    22:29
  • Plane trusses IV – Solved examples for calculating forces in a simple truss by method of joints
    26:58
  • Plane trusses V – Solved examples for calculating forces in a simple truss by method of joints
    24:14
  • Plane trusses VI: Method of sections for calculating forces in a simple truss
    10:18
  • Dry friction I – introduction with an example
    22:05
  • Dry friction II – a solved example
    16:08
  • Dry friction III – Dry thrust bearing and belt friction with demonstration
    18:26
  • Dry friction IV – Screw friction and rolling friction
    27:48
  • Dry friction V: Solved examples
    24:58
  • Properties of plane surfaces I – First moment and centroid of an area
    31:17
  • Properties of plane surfaces II – Centroid of an area made by joining several plane surfaces
    12:54
  • Properties of plane surfaces III – Centroid of a distributed force and its relation with centre…
    11:57
  • Properties of plane surfaces IV – solved examples of calculation of first moment and centroid…
    24:26
  • Properties of plane surfaces V- Second moment and product of an area and radius of gyration
    18:54
  • Properties of plane surfaces VI – Parallel axis transfer theorem for second moment
    12:15
  • Properties of plane surfaces VII – transformation of second moment and product of an area under rota
    22:01
  • Properties of plane surfaces VIII – second moment and product of an area, solved examples
    24:18
  • Method of virtual work I – degrees of freedom, constraints and constraint forces
    20:24
  • Method of virtual work II – virtual displacement, virtual work and equilibrium condition
    19:55
  • Method of virtual work III – solved examples
    21:29
  • Motion of a particle in a plane in terms of planar polar coordinates
    24:23
  • Planar polar coordinates: solved examples
    20:36
  • Description of motion in cylindrical and spherical coordinate systems
    16:14
  • Using planar polar, cylindrical and spherical coordinate systems: solved examples
    39:26
  • Motion with constraints, constraint forces and free body diagram
    21:55
  • Motion with constraints – solved examples
    37:33
  • Motion with dry friction – solved examples
    54:28
  • Motion with drag – solved examples
    55:27
  • Equation of motion in terms of linear momentum and the principle of conservation of linear momentum
    15:50
  • Linear momentum and centre of mass
    07:54
  • Momentum transfer, impulse and force due to a stream of particles hitting an object
    11:56
  • Momentum and the variable mass problem
    12:48
  • Linear momentum – solved examples
    49:11
  • Work and energy I – work energy theorem; conservative and non-conservative force fields
    17:57
  • Work and energy II – Definition of potential energy for conservative forces; total mechanical energy
    15:38
  • Work and energy III – Two solved examples using conservation principles
    11:16
  • Work and energy IV – Further discussion on potential energy
    09:29
  • Work and energy V – Solved examples
    22:21
  • Work and energy VI – Applying conservation principles to solve a collision problem
    20:03
  • Work and energy VII – Solved examples
    26:42
  • Rigid body motion I – degrees of freedom and number of variables required to describe motion
    11:51
  • Rigid body motion II – Equation of motion for a single particle in terms of angular momentum
    24:04
  • Rigid body motion III – Conservation of angular momentum; angular momentum for a collection
    24:19
  • Rigid body motion IV – applying angular momentum conservation, a solved example
    10:54
  • Rigid body motion V (fixed axis rotation) – some demonstrations of conservation of angular momentum
    22:06
  • Rigid body motion VI (fixed axis rotation) – Some more demonstrations and related problems
    23:24
  • Rigid body motion VII (fixed axis rotation) – Kinetic energy and moment of inertia for fixed axis
    06:42
  • Rigid body motion VIII (fixed axis rotation) – solved examples for calculating moment
    18:48
  • Rigid body motion –IX (fixed axis rotation): solved examples
    19:11
  • Rigid body motion X – rotation and translation with axis moving parallel to itself
    13:33
  • Rigid body motion XI – solved examples for rotation and translation
    27:03
  • Rigid-body dynamics XII – Some demonstrations on general motion of rigid bodies
    10:10
  • Rigid-body dynamics XIII – Infinitesimal angles as vector quantities and change of a vector
    22:50
  • Rigid-body dynamics XIV – Angular velocity and the rate of change of a rotating vector
    07:28
  • Rigid-body dynamics XV – Relationship between angular momentum and angular velocity
    12:33
  • Rigid-body dynamics XVI: Solved examples
    09:05
  • Rigid body motion XVII – A review of the relation between angular momentum and angular velocity
    13:10
  • Rigid body motion XVIII- Solved examples for calculating rate of change of angular momentum and torq
    31:11
  • Rigid body dynamics XIX
    14:33
  • Rigid body dynamics XX
    34:49
  • Rigid body dynamics XXI
    48:04
  • Simple harmonic motion I
    11:16
  • Simple harmonic motion II
    18:28
  • Simple Harmonic Motion III – Solved Example
    13:19
  • Simple Harmonic Motion IV – Energy of an Oscillator
    17:08
  • Simple harmonic motion V – Solved Example
    34:50
  • Simple harmonic motion VI
    14:10
  • Simple harmonic motion VII
    17:14
  • Simple Harmonic Motion VIII
    11:36
  • Simple harmonic motion IX
    20:14
  • Simple harmonic motion X
    10:50
  • Simple harmonic oscillator X
    21:25
  • Simple harmonic oscillator XI
    15:31
  • Simple harmonic oscillator XI (Contd.)
    09:23
  • Simple harmonic oscillator XII
    17:19
  • Solved examples
    39:24
  • Method of Virtual Work
    42:24
  • Equation of Motion in a Uniformly Accelerating Frame
    12:55
  • Motion Described in a uniformly accelerating frame
    21:47
  • Motion Described in a uniformly accelerating frame (Contd.)
    22:00
  • Motion in a uniformly rotating frame
    20:00
  • Motion in a uniformly rotating frame (Contd.)
    17:15
  • Motion in a uniformly rotating frame (Contd.)
    18:38
  • Demonstration on effects of pseudo forces in a rotating frame
    13:00
  • Problem1
    35:45
  • Problem2
    33:32
  • Problem3
    41:09
  • Problem4
    23:08
  • Problem5
    40:35
  • Problem6
    32:08
  • Problem7
    22:09
  • Problem8
    49:18
  • Problem9
    46:14

Applied Mechanics

Mechanics of Materials

Theory of Machines

Mechanical Vibrations

Design of Machine Elements

Fluid Mechanics

Heat Transfer

Thermodynamics

Basics of Materials Engineering

Principle of Industrial Engineering

Fundamentals of manufacturing processes

Mechanics of Machining

Metal Cutting And Machine Tools

Machining and Machine Tool Operations

Metrology and Inspection

Computer Integrated Manufacturing

Production and Operation Management

Operations Management

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