Mechanical Engineering Preparation

Engineering Mechanics

Introduction to Vectors

15:40
Addition and subtraction of vectors

13:57
Multiplying vectors

11:33
Introduction to vectors: solved examples I

38:33
Introduction to vectors: solved examples II

19:55
Transformation of vectors under rotation

22:55
Vector products and their geometric interpretation

16:39
Vector Product: Kronecker Delta and Levi-Civita symbols-I

15:51
Vector Product: Kronecker Delta and Levi-Civita symbols-II

14:12
Equilibrium of rigid bodies – Forces and torques

21:00
Calculating torques and couple moments – I

19:32
Calculating torques and couple moments – II

16:53
Finding a force and a couple equivalent to an applied force

11:21
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

15:00
Forces in different geometric configurations

17:10
Plane trusses I – Building a truss and condition for it to be statically determinate

22:17
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

22:30
Plane trusses IV – Solved examples for calculating forces in a simple truss by method of joints

26:59
Plane trusses V – Solved examples for calculating forces in a simple truss by method of joints

24:15
Plane trusses VI: Method of sections for calculating forces in a simple truss

10:18
Dry friction I – introduction with an example

22:06
Dry friction II – a solved example

16:08
Dry friction III – Dry thrust bearing and belt friction with demonstration

18:27
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

31:18
Properties of plane surfaces II – Centroid of an area made by joining several plane surfaces

12:55
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…

24:27
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

12:16
Properties of plane surfaces VII – transformation of second moment and product of an area under rota

22:02
Properties of plane surfaces VIII – second moment and product of an area, solved examples

24:19
Method of virtual work I – degrees of freedom, constraints and constraint forces

20:25
Method of virtual work II – virtual displacement, virtual work and equilibrium condition

19:56
Method of virtual work III – solved examples

21:29
Motion of a particle in a plane in terms of planar polar coordinates

24:24
Planar polar coordinates: solved examples

20:37
Description of motion in cylindrical and spherical coordinate systems

16:15
Using planar polar, cylindrical and spherical coordinate systems: solved examples

39:27
Motion with constraints, constraint forces and free body diagram

21:56
Motion with constraints – solved examples

37:34
Motion with dry friction – solved examples

54:29
Motion with drag – solved examples

55:28
Equation of motion in terms of linear momentum and the principle of conservation of linear momentum

15:51
Linear momentum and centre of mass

07:48
Momentum transfer, impulse and force due to a stream of particles hitting an object

11:57
Momentum and the variable mass problem

12:49
Linear momentum – solved examples

49:12
Work and energy I – work energy theorem; conservative and non-conservative force fields

17:58
Work and energy II – Definition of potential energy for conservative forces; total mechanical energy

15:39
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

22:22
Work and energy VI – Applying conservation principles to solve a collision problem

20:03
Work and energy VII – Solved examples

26:43
Rigid body motion I – degrees of freedom and number of variables required to describe motion

11:52
Rigid body motion II – Equation of motion for a single particle in terms of angular momentum

24:05
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

10:55
Rigid body motion V (fixed axis rotation) – some demonstrations of conservation of angular momentum

22:07
Rigid body motion VI (fixed axis rotation) – Some more demonstrations and related problems

23:25
Rigid body motion VII (fixed axis rotation) – Kinetic energy and moment of inertia for fixed axis

06:43
Rigid body motion VIII (fixed axis rotation) – solved examples for calculating moment

18:49
Rigid body motion –IX (fixed axis rotation): solved examples

19:12
Rigid body motion X – rotation and translation with axis moving parallel to itself

13:34
Rigid body motion XI – solved examples for rotation and translation

27:04
Rigid-body dynamics XII – Some demonstrations on general motion of rigid bodies

10:11
Rigid-body dynamics XIII – Infinitesimal angles as vector quantities and change of a vector

22:51
Rigid-body dynamics XIV – Angular velocity and the rate of change of a rotating vector

07:29
Rigid-body dynamics XV – Relationship between angular momentum and angular velocity

12:34
Rigid-body dynamics XVI: Solved examples

09:06
Rigid body motion XVII – A review of the relation between angular momentum and angular velocity

13:11
Rigid body motion XVIII- Solved examples for calculating rate of change of angular momentum and torq

31:12
Rigid body dynamics XIX

14:34
Rigid body dynamics XX

34:50
Rigid body dynamics XXI

48:05
Simple harmonic motion I

11:17
Simple harmonic motion II

18:29
Simple Harmonic Motion III – Solved Example

13:20
Simple Harmonic Motion IV – Energy of an Oscillator

17:09
Simple harmonic motion V – Solved Example

34:51
Simple harmonic motion VI

14:10
Simple harmonic motion VII

17:14
Simple Harmonic Motion VIII

11:36
Simple harmonic motion IX

20:15
Simple harmonic motion X

10:51
Simple harmonic oscillator X

21:26
Simple harmonic oscillator XI

15:32
Simple harmonic oscillator XI (Contd.)

09:24
Simple harmonic oscillator XII

17:20
Solved examples

39:25
Method of Virtual Work

42:25
Equation of Motion in a Uniformly Accelerating Frame

12:56
Motion Described in a uniformly accelerating frame

21:47
Motion Described in a uniformly accelerating frame (Contd.)

22:01
Motion in a uniformly rotating frame

20:01
Motion in a uniformly rotating frame (Contd.)

17:16
Motion in a uniformly rotating frame (Contd.)

18:39
Demonstration on effects of pseudo forces in a rotating frame

13:00
Problem1

35:45
Problem2

33:33
Problem3

41:10
Problem4

23:09
Problem5

40:36
Problem6

32:09
Problem7

22:09
Problem8

49:19
Problem9

46:15

Applied Mechanics

Mechanics of Materials

Concepts and equations in this course

13:04
Objectives and prerequisite

22:15
Linear Algebra

26:13
Vector Algebra

14:59
Representation of Vector

31:01
Why this course?

08:50
Concept of Force

07:02
Definition of a body

15:55
Motion and Displacement field

21:06
Traction

07:56
Properties of traction

17:29
Definition of stress tensor and linear function

11:53
Tensor Algebra

18:37
Meaning of components of the stress tensor

18:30
Transformation of stress components

08:31
Mohr’s Circle derivation

17:47
Example 1: Construction of Mohr’s circle

08:55
Example 3: Transformation of stress components

18:43
Uniaxial stress

09:58
Hydrostatic, pure shear and deviatoric stress

11:57
Biaxial and Plane state of stress

06:14
Extreme stress for 3D stresses

18:49
Stresses in the Octahedral plane

07:22
2D Equilibrium equations

18:25
3D Equilibrium equations

28:56
Stretch ratio and strain

18:33
Curves and arc Length

16:20
Gradient

16:13
Deformation and displacement Gradient

06:08
Right Cauchy Green Deformation tensor

13:49
Homogeneous deformation

08:21
Engineering strain

14:32
Change in Angle

22:23
Example 2: Extremum normal and shear stress

18:16
Extremum shear stress

18:28
Transformation of strain components/ Strain Rosette

15:13
Compatibility condition

16:17
Constitutive relation

15:56
Young’s Modulus and Poisson’s Ratio

26:47
Shear Modulus

04:10
Bulk Modulus

13:52
Restriction on material parameters

15:01
Thermal strain

08:22
Strain energy, load potential and total potential

20:36
Stepped shaft subjected to axial force

21:47
Inhomogeneous bar subjected to axial force

14:04
Stepped shaft subjected to raise in temperature

14:55
Traction in member subjected to bending

20:12
Governing equilibrium equations

16:49
Displacement field

18:33
Bending equation

15:06
Radius of curvature

11:01
Shear force and bending moment diagram

13:54
Variation of axial stress

08:44
Deflected shape and rotation of cross section

16:24
Expression to find shear stress

23:53
Finding centroid of a cross section

07:23
Parallel axis theorem and its application

15:12
Vertical shear stress in I section

16:16
Horizontal shear stress in I section

12:38
Connection design

15:38
Definition of shear center

07:38
Shear center of Channel section

15:56
Expression to find shear center

18:13
Shear force and bending moment diagram

14:53
Deflected shape and rotation of cross section

27:55
Finding allowable load

12:45
Modified bending equation

09:25
Bending of a composite beam

20:46
Connection design

09:56
Moment of Intertia about arbitrarily oriented axis

15:42
Example: Angle section

18:33
Bending equation for bending about principal axis

19:17
Bending equation about arbitrary axis

11:34
Neutral axis

08:50
Load not about principal axis

33:19
Load about principal axis

05:15
Displacement field

15:13
Torsion equation

09:52
Example problems

17:06
Expression relating angle of twist with torsion and shear stress

11:18
Example problems: Open sections

13:07
Thin walled closed sections

19:30
Example problems: Thin walled sections

06:59
Cylindrical polar coordinate system

13:05
Displacement field

05:39
Governing differential equation and solution

20:37
Example problems : Thick walled cylindrical vessel

14:36
Thin walled pressure vessels

25:50
General Principals

12:25
Different failure modes

08:18
Tresca Condition

25:39
von Mises condition

29:29
Maximum normal stress or rankine condition

04:50
Mohr – Columb condition

06:51
Drucker-Prager Condition

04:19
General Concepts

14:20
Euler critical load for simply supported column

33:04
Euler critical load for column with any boundary condition

18:46
Secant formula

24:51
Pressure vessel and failure theory

30:44
Determination of maximum load carrying capacity of a simple truss

16:40

Theory of Machines

Introduction-Mechanisms

05:44
Kinematic Pairs

05:21
Constrained Motion

03:27
Kinematic Chain

02:32
Degree Of Freedom

04:55
Grashof’s Law

01:25
Numerical On Degree Of Freedom

05:25
Concept Of Relative Velocity

08:50
Relative Velocity Of Points On Same Link

03:43
Velocity Analysis Of 4 Bar Mechanism

04:38
Instantaneous Centre Method

06:22
Types Of Instantaneous Centres

06:19
Arnold-Kennedy Theorem

02:23
Angular Velocities Of Link

03:39
Total Acceleration Of A Link

03:48
Absolute Acceleration Of A Link

03:08
Acceleration Analysis For A 4 Bar Chain

04:39
Coriolis Acceleration

05:46
Angular Velocity Radio Of A Flat Belt

04:39
Effect Of Slip

04:53
Length Of Open Belt

08:26
Length Of Cross Belt

05:23
Ratio Of Belt Tensions

04:55
Centrifugal Tension

03:21
Condition for Maximum Power Transmission

03:10
Problem 1 On Belts

06:28
Problem 2 On Belts

05:20
Ratio Of Tension In V-Belts

04:49
Problem On V-Belts

08:23
Chain Drive

04:18
Problem On Chain Drive

05:28
Rope Drive

02:49
Problem 1 On Chain Drive

04:42
Types Of Cams And Followers

06:19
Follower Motion-Simple Harmonic Motion (SHM)

09:26
Follower Motion-Uniform Acceleration and Deceleration

03:11
Follower Motion With Uniform Velocity

02:29
Follower Motion Parabolic Motion

06:41
Cycloidal Motion

05:05
Problem 1 On Cams

05:28
Problem 2 On Cams

05:54
Problem 3 On Cams

03:50
Theory of Machines Types Of Gears

07:49
Gear Terminology

11:31
Law Of Gearing

09:23
Tooth Profile

05:19
Problem 1 On Gears

04:08
Problem 2 On Gears

04:04
Gear And Gear Trains

10:07
Minimum Number Of Teeth-Pinion

03:29
Problem 3 On Gears And Gear Trains

04:25
Problem 4 On Gears And Gear Trains

06:33
Only One Gear On Each Shaft(SImple Gear Train)

04:01
Compound Gear Trains

05:18
Reverted Gear Train

02:12
Epicyclic Gear Train

03:12
Tabular Method For Epicyclic Gear Trains

03:05
Problem 1 On Gear Trains

04:11
Problem 2 On Gear Trains

03:24
Problem 3 On Gear Trains

05:25
Types Of Governors

02:16
Watt Governors

05:45
Porter Governor

07:58
Proell Governor

05:38
Problem On Walt Governor

03:14
Problem On Porter Governor

04:57
Problem On Proell Governor

05:40
Sensitiveness Governor

02:52
Stability Of A Governor

01:24
Hartnell Governor

12:07
Isochronism

00:48
Problem On Hartnell Governors

06:35
Balancing Of Single Rotating Mass

03:32
Balancing Of Single Rotating Mass By Two Balancing Mass

06:57
Many Masses Rotating In the Same Plane

05:34
Many Masses Rotating In Different Plane

09:50
Problem On Balancing

13:19
Balancing Of Reciprocating Engine

05:08
Partial Primary Balance

05:41
Processional Motion

08:58
Gyroscopic Couple For A Plane Disc

03:14
Problem 1 On Gyroscopic Motion

02:33
Problem 2 On Gyroscopic Motion

03:32
Problem 3 On Gyroscopic Motion

07:19
Gyroscopic Effects On An AeroPlane

04:08
Gyroscopic Effects On a Four Wheel Vehicle

08:54
Numerical On Gyroscopic Effect On Four Wheel Vehicle

10:10
Friction Introduction

06:24
Force Analysis Of Body Resting On A Horizontal Plane

03:43
Body Resting On Inclined Plane With Inclined Force

06:11
Body Resting On Inclined Plane With Horizontal Force

04:08
Efficiency On An Inclined Plane

06:18
Theory of Machines Screw Jack

05:32
Efficiency Of Screw Jack

04:20
Self Locking And Over Hauling Screw

02:39
Screw With V- Threads

01:51
Problem On Screw Jack

05:50
Problem On V-Threads

04:54
Flat Pivot Bearing – Uniform Pressure

03:46
Flat Pivot Beaming Uniform Wear

03:17
Problem 1 On Flat Pivot Bearing

03:29
Problem 2 On Flat Pivot Bearing

04:45
Motion Analysis Of Reciprocating Mechanism

06:29
Velocity Of Piston

02:47
Acceleration Of Piston

02:01
Angular Velocity Of Connecting Rod

02:29
Angular Acceleartion Of Connecting Rod

04:50
Problem On Inertia Force

04:27
Equilibrium Forces In Out Stroke

04:47
Crank Effort

03:15
Turning Moment Diagram For A 4 Stroke Cycle

03:03
Determination Of Maximum Fluctuation Of Energy

03:57
Coefficient Of Fluctuation Of Energy

03:16
Coefficient Of Fluctuation Of Speed

02:44
Energy Stored In A Fly Wheel

05:09
Problem 1 On Fly Wheel

03:23
Problem 2 On Fly Wheel

04:24
Problem 3 On Fly Wheel

07:15
Problem 4 On Fly Wheel

05:14
Single Block Or Shoe Brake

05:04
Pivoted Shoe Brake

10:03
Double Shoe Brake

06:54
Simple Band Brake

02:04
Differential Band Brake

04:30
Braking Of A Vehicle

09:32
Problem 1 On Brakes

03:19
Problem 2 On Brakes

06:58
Problem 3 On Brakes

05:12
Single Plate Clutch

06:10
Single Plate Clutch – Uniform Wear

03:19
Cone Clutch – Uniform Pressure

07:23
Cone Clutch – Uniform Wear

02:50
Clutch example problem 1

07:18
Clutch example problem 2

03:45
Clutch example problem 3

05:01
Elements Of A Vibratory System

03:49
Types Of Vibration

04:36
Important Terms Used In Vibratory System

05:43
Newton’s Method

06:55
Spring Combinations

03:16
Torsional Vibrations

03:12
Free Damped Vibrations

06:34
Overdamped System

02:21
Critically Damped System

02:08
Under Damped Vibrations

02:53

Mechanical Vibrations

Overview of the Course, Practical and Research Trends

01:02:52
Harmonic and Periodic Motions, Vibration Terminology

59:09
Vibration Model, Equation of Motion-Natural Frequency

59:05
Energy Method, Principle of Virtual Work

59:16
Viscously Damped Free Vibration Special Cases: Oscillatory

58:47
Logarithmic Decrement Experimental Determination of Damping Coefficient Hysteresis Loop

59:31
Coulomb Damping other Damping Models

55:22
Forced Harmonic Vibration, Magnification Factor

56:42
Laplace Transform, Superposition Theorem

58:26
Rotor Unbalance and Whirling of Shaft, Transmissibility

58:32
Support Motion, Vibration Isolation

59:38
Sharpness of Resonance, Vibration Measuring Instruments

58:35
Generalized and Principle Coordinates, Derivation of Equation of Motion

59:53
Lagranges’s Equation

59:22
Coordinate Coupling

01:00:18
Forced Harmonic Vibration

58:05
Tuned Absorber, Determination of Mass Ratio

59:28
Tuned and Damped Absorber, Untuned Viscous Damper

59:11
Derivation of Equations of Motion, Influence Coefficient Method

01:00:01
Properties of Vibrating Systems: Flexibility & Stiffness Matrices, Reciprocity Theorem

57:37
Modal Analysis: Undamped

59:04
Modal Analysis: Damped

59:01
Simple Systems With One Two or Three Discs Geared System

59:00
Multi-Degree of Freedom Systems-Transfer Matrix Method Branched System

01:02:25
Derivation of Equations of Motion Part 1-Newton’s and Hamilton’s Principle

58:24
Derivation of Equations of Motion Part 2-Newton’s and Hamilton’s Principle

59:53
Vibration of Strings

56:59
Longitudinal and Torsional Vibration of Rods

01:00:59
Transverse Vibration of Beams, Equations of Motion and Boundary Conditions

58:43
Transverse Vibration of Beams: Natural Frequencies and Mode Shapes

59:51
Rayleigh’s Energy Method

01:00:02
Matrix Iteration Method

01:00:11
Durkerley, Rayleigh-Ritz and Galerkin Method

58:54
Finite Element Formulation for Rods, Gear Train and Branched System

01:08:10
Finite Element Formulation for Beams: Galerkin’s Method

58:25
Global Finite Element Assembly and Imposition of Boundary Conditions

59:51
Vibration Testing Equipments: Signal Measurements

01:00:13
Vibration Testing Equipments: Signal Analysis

55:53
Field Balancing of Rotors

57:46
Condition Monitoring

45:31

Design of Machine Elements

Fluid Mechanics

Introduction and Fundamental Concepts – I

51:58
Introduction and Fundamental Concepts – II

51:48
Introduction and Fundamental Concepts – III

49:56
Fluid Statics Part – I

54:01
Fluid Statics Part – II

52:50
Fluid Statics Part – III

57:27
Fluid Statics Part – IV

52:13
Fluid Statics Part -V

51:57
Fluid Statics Part -VI

49:24
Kinematics of Fluid Part – I

53:26
Kinematics of Fluid Part – II

49:15
Kinematics of Fluid Part – III

52:01
Conservation Equations in Fluid Flow Part – I

49:03
Conservation Equations in Fluid Flow Part – II

48:56
Conservation Equations in Fluid Flow Part – III

46:54
Conservation Equations in Fluid Flow Part – IV

47:52
Conservation Equations in Fluid Flow Part – V

48:29
Conservation Equations in Fluid Flow Part – VI

49:11
Conservation Equations in Fluid Flow Part – VII

49:15
Conservation Equations in Fluid Flow Part – VIII

44:47
Conservation Equations in Fluid Flow Part – IX

51:59
Fluid Flow Applications Part – I

58:08
Fluid Flow Applications Part – II

50:34
Fluid Flow Applications Part – III

47:34
Fluid Flow Applications Part – IV

48:05
Fluid Flow Applications Part – V

52:39
Fluid Flow Applications Part – VI

58:37
Fluid Flow Applications Part – VII

50:01
Incompressible Viscous Flows Part I

47:53
Incompressible Viscous Flows Part II

52:48
Incompressible Viscous Flows Part III

49:43
Incompressible Viscous Flows Part IV

50:45
Application of ViscousFlow Through Pipes Part I

50:41
Application of ViscousFlow Through Pipes Part II

53:13
Application of ViscousFlow Through Pipes Part III

48:58
Principles of Similarity Part I

42:13
Principles of Similarity Part II

52:10
Principles of Similarity Part III

01:00:26
Flow of Ideal Fluids Part I

58:11
Flow of Ideal Fluids Part II

49:56
Flows with a Free Surface Part I

52:17
Flows with a Free Surface Part II

52:29
Flows with a Free Surface Part III

55:49
A Few Unsteady Flow Phenomena in Practice Part I

54:24
A Few Unsteady Flow Phenomena in Practice Part II

50:25
Introduction to Laminar Boundary Layer Part I

50:26
Introduction to Laminar Boundary Layer Part II

51:06
Introduction to Turbulent Flow Part I

46:57
Introduction to Turbulent Flow Part II

58:07

Heat Transfer

Introduction to Heat Transfer

34:19
Introduction to Heat Transfer (Contd.)

35:16
Heat Diffusion Equation

32:21
Relevant Boundary Conditions in Conduction

46:29
One Dimensional Steady State Conduction

38:37
Temperature Distribution in Radial Systems

36:43
Tutorial Problem on Critical Insulation Thickness

37:11
Heat Source Systems

33:43
Tutorial Problems of Heat Generating Systems

40:09
Transient Conduction

43:25
Lumped Capacitance (Contd.) and Tutorial Problem

34:47
Transient heat Conduction

33:33
Transient Conduction – Heisler Chart

40:23
Heat Transfer from Extended Surface

42:08
Fins and General Conduction Analysis

43:12
Fundamentals of Convection

45:14
Equations of Change for Non-isothermal Systems

39:28
Equations of Change for Non-isothermal Systems – continued

37:53
Tutorial on the Application of Energy Equation

34:07
Nusselt Number of a heated sphere in Stagnant Air

35:29
Momentum and Thermal Boundary Layers

25:03
The Flat Plate in Parallel Flow – Hydrodynamics and Momentum Transfer

33:18
The Flat Plate in Parallel Flow – Heat Transfer

33:28
The Effects of Turbulence

37:47
Turbulent External Flow

35:27
Heat and Momentum Transfer Analogy

40:36
Mixed Boundary Layers

32:30
Tutorial Problem on External Flow and Behavior of Heat Transfer Coefficient

32:39
Tutorial Problem in External Flow and Convection

41:00
Tutorial Problem in External Flow and Convection

31:17
Tutorial Problem in External Flow and Convection

31:19
Internal Flow Heat Transfer

40:36
Internal Flow Heat Transfer (contd.)

33:20
Internal Flow Heat Transfer (Contd.)

39:25
Internal Flow and Heat Transfer (Contd.)

37:56
Internal Flow and Heat Transfer (Tutorial)

37:07
Free Convection

38:04
Heat Exchangers

32:32
Heat Exchangers (Contd.)

36:22
Heat Exchangers (Contd.)

31:52
Tutorial Problems on Heat Exchanger Calculations

37:43
Tutorial Problem on LMTD and Dirt Factor

30:09
Epsilon-NTU Method – 1

37:07
Epsilon-NTU Method – 1 (Continued)

34:47
Tutorial Problems on Epsilon – NTU Methods

30:55
Tutorial Problems on Epsilon – NTU Methods

30:20
Boiling, Evaporation and Evaporators

41:19
Radiation – Fundamental Concepts

35:11
Spectral Blackbody Radiation Intesity and Emissive Power

34:18
Wein’s Law, Stephen Boltzmann Law, Blackbody Radiation Function, Tutorial Problem

35:41
Kirchhoff’s Law

39:27
Tutorial on Emissivity, Absroptivity and Blackbody Radiation Functions

39:39
Solar Radiation and the Concept of View Factors

36:43
Determination of View Factors

33:18
Radiosity Blackbody Radiation Exchanges, Relevant Problem

35:04
Network Method for Radiation Exchange in an Enclosure

30:46
Network Method – Two and Three Zone Enclosures

32:10
Tutorial Problem on Radiation Exhange using the Network Method

31:28
Radiation Shields

35:12
Gaseous Radiation (Participating Medium)

37:48

Thermodynamics

Basic concepts and definitions – Part 1

19:50
Basic concepts and definitions – Part 2

20:24
Basic concepts and definitions – Part 3

37:25
Basic concepts and definitions – Part 4

14:24
Tutorial problems on exact and inexact differential

12:33
Work – Part 1

19:09
Work – Part 2

13:44
Work – Part 3

17:13
Work – Part 4

28:37
Work – Part 5

13:18
Tutorial problem on ‘Work’ – Part 1

15:01
Tutorial problem – Part 2

18:46
Tutorial problem on ‘Work’ – Part 3

13:55
Tutorial problem on ‘Work’ – Part 4

13:39
Zeroth law of thermodynamics

14:05
Methods of temperature measurement

15:34
Modes of heat transfer

21:17
Tutorial problem on ‘Modes of heat transfer

09:04
Tutorial problem on ‘Methods of temperature measurement

18:36
First law of thermodynamics

29:00
Tutorial problem

10:02
Tutorial problem

18:48
Heat and work interactions for a system

11:28
Pure substance

15:00
Ideal gas – Part 1

11:29
Ideal gas – Part 2

22:18
Ideal gas – Part 3

07:05
Ideal gas – Part 4

16:30
Ideal gas – Part 5

14:32
Tutorial problem – Part 1

07:36
Tutorial problem – Part 2

15:00
Tutorial problem – Part 3

19:48
Tutorial problem – Part 4

16:25
Tutorial problem – Part 5

06:32
Tutorial problem – Part 6

07:39
Tutorial problem – Part 7

12:53
Specific heats at constant pressure and constant volume

11:59
Tutorial problem – Part 1

13:51
Tutorial problem – Part 2

24:18
Tutorial problem – Part 3

19:01
Tutorial problem – Part 4

18:26
Beyond ideal gases – Part 1

19:45
Beyond ideal gases – Part 2

14:18
Two phase system – Part 1

21:40
Two phase system – Part 2

38:01
Two phase system: water and steam

30:16
Tutorial problems (2 numbers)

37:13
Tutorial problem – Part 1

34:08
Tutorial problem – Part 2

16:30
Tutorial problem – Part 3

11:58
Tutorial problems on two-phase systems(2 numbers)

33:14
Tutorial problem (1 number)

23:08
Rate equation of the first law of thermodynamics for a control mass and a control volume

34:02
Energy equation for a steady-state, steady-flow process in selected engineering devices

38:09
Tutorial problems (3 numbers)

34:01
Tutorial problem – Part 1

14:32
Tutorial problem – Part 2

19:45
Quasi-static process revisited: Work against an external force

17:35
Second law of thermodynamics: limitations of the first law of thermodynamics

16:42
Second law of thermodynamics: direct and reverse heat engine

35:47
Second law of thermodynamics: Kelvin-Planck and Clausius statements

11:31
Second law of thermodynamics: reversible process

12:41
Second law of thermodynamics: Carnot’s cycle and theorems

24:34
Second law of thermodynamcis: absolute temperature scale

17:39
Tutorial problems (2 numbers)

15:19
Tutorial problem (1 number)

16:03
Tutorial problem (1 number)

28:52
Tutorial problem (2 numbers)

12:39
Second law of thermodynamics: Clausius’s inequality

18:35
Entropy – Part 1

30:23
Entropy – Part 2

18:34
Entropy – Part 3

38:55
Entropy – Part 4

23:55
Entropy – Part 5

14:50
Entropy – Part 6

27:59
Entropy – Part 7

18:34
Tutorial problem (1 number)

15:09
Tutorial problem (1 number)

20:00
Tutorial problem (1 number)

13:54
Tutorial problems (2 numbers)

24:11
Exergy – Part 1

11:57
Exergy – Part 2

18:12
Exergy – Part 3

24:10
Thermodynamics cycles: Rankine cycle

31:37
Tutorial problem (1 number)

33:43
Thermodynamics cycles: Brayton cycle

24:56
Tutorial problem (1 number)

11:41
Thermodynamics cycles: vapor compression refrigeration cycle

25:17
Tutorial problem (1 number)

25:14

Basics of Materials Engineering

Introduction

33:09
Material Property Landscape

19:37
Crystal Structure – 1 (Platonic Solids)

26:17
Crystal Structure – 2 (Unit Cell, Lattice, Crystal)

11:49
Crystal Structure – 3 (Bravais lattice, Symmetry in Crystals)

15:54
Crystal Structure – 4 (Miller Indices for Crystallographic Points and Directions)

15:41
Crystal Structure – 5 (Miller-Bravais Indices, Linear and Planar Density)

22:55
Crystal Structure – 6 (Planar desnity, Close-Packed Structures, Stacking Faults)

23:50
Crystal Structure – 7 (Single Crystal and Polycrystalline Materials)

11:59
Crystal Structure – 8 (X-Ray Diffraction and Determination of Structure)

09:50
Defects in Crystalline Materials – 1 (Types of Crystalline Defects)

12:50
Defects in Crystalline Materials – 1 (Point Defects)

06:50
Defects in Crystalline Materials – 1 (Equilibrium Concentration of Vacancies)

17:38
Defects in Crystalline Materials – 1 (Theoretical Shear Strength)

09:00
Defects in Crystalline Materials – 2 (Effect of Point Defects)

20:29
Defects in Crystalline Materials – 2 (Point Defects and Solid Solutions)

25:34
Defects in Crystalline Materials – 3

31:49
Defects in Crystalline Materials – 4 (Slip Systems, Burger’s Vector )

22:19
Defects in Crystalline Materials – 4 (Slip in Single Crystals )

22:06
Defects in Crystalline Materials – 5 (Different Stages of Slip )

26:46
Defects in Crystalline Materials – 5 (Geometry & Slip, Stress Field Around )

14:45
Defects in Crystalline Materials – 6 (Twinning, Interfacial Defects )

19:21
Defects in Crystalline Materials – 6 (Strengthening Mechanisms)

21:30
Defects in Crystalline Materials – 7 (Plastic deformation)

18:33
Mechanical Properties of Materials (Concept of Stress Tensor)

20:58
Mechanical Properties (Tension Test-Elastic Deformation)

25:19
Mechanical Properties (Tension Test – Plastic Deformation)

21:14
Mechanical Properties (Tension Test – Plastic Deformation)

40:13
Mechanical Properties (Hardness Test)

20:47
Static Failure Theories (Introduction, Definition of Failure)

27:18
Static Failure Theories (General form of failure theory)

45:54
Static Failure Theories (Distortion Energy Theory)

45:06
Static Failure Theories (Maximum Shear Stress Theory)

12:00
Static Failure Theories (Design Problems)

10:43
Static Failure Theories (Failure of Brittle Materials)

07:28
Static Failure Theories (Coulomb-Mohr and Modified Coulomb-Mohr)

29:04
Static Failure Theories (Notches and Stress Concentration)

19:49
Introduction to Fracture Mechanics, Griffith’s Analysis of a Cracked Body

43:25
Fracture Mechanics (Energy Release Rate)

25:44
Fracture Mechanics (Crack Resistance, Stress Intensity Factor)

20:44
Fatigue Failure of Materials (Introduction, Historical Events, S-N Diagram)

39:53
Fatigue Failure of Materials (S-N Diagram, Types of Time Varying Loads)

18:57
Fatigue Failure of Materials (High Cycle Fatigue, Low Cycle Fatigue)

25:24
Fatigue Failure of Materials (Rotating Beam Bending Test)

31:33
Fatigue Failure Theories (Fatigue strength correction factors)

30:06
Problems on Fatigue Failure -1 S N diagram and Corrected endurance strength

37:12
Fatigue Failure of Materials (Features of Fatigue Failure)

18:14
Fatigue Failure of Materials (Effect of Mean Stress)

13:39
Fatigue Failure of Materials (Multiaxial Fatigue and Variable Amplitude Loading)

17:15
Fatigue Failure of Materials (Fatigue Stress Concentration Factor)

21:39
Fatigue Failure of Materials (Fatigue Crack Growth, Paris’ law)

26:51
Problems on Fatigue Failure – 2 Effect of mean stress, Fatigue crack growth

34:29
Problems on Fatigue Failure – 3 (Effect of Notch, Multiaxial Loading)

01:05:31
Phase Diagrams (Introduction)

12:39
Phase Diagrams (Language of Phase Diagrams, Types of Binary Phase Alloys)

32:35
Phase Diagrams (Tie line, Lever Rule)

27:26
Phase Diagrams (Type 1: Isomorphous Alloys)

22:32
Phase Diagrams (Congruent Melting Alloys, Type II Alloys, Eutectic Reaction)

39:13
Phase Diagrams (Type III Alloys with Partial Solubility in Solid State)

31:20
Phase Diagrams (Congruent melting alloys, Peritectic Reaction, Monotectic Reaction)

38:54
Phase Diagrams (Allotropy, Eutectoid and Peritectoid Reactions)

13:06
Phase Diagrams (Iron-Iron Carbide Phase Diagram)

41:18
Kinetics of Phase Transformations (Homogeneous Nucleation)

35:50
Kinetics of Phase Transformations (Heterogeneous Nucleation)

17:51
Isothermal Transformation Diagram

33:21
Martensite Transformation, C-C-T Diagram

37:51
Heat Treatment of Steels (Annealing and Normalizing)

25:24

Principle of Industrial Engineering

Introduction

28:09
Introduction: Developments, Objectives, and Functions

38:19
Introduction: Functions and Tools

38:55
Tool of IE and Organizational Structure

31:25
Organizational Structure

31:22
Organizational Structure: Roles

30:44
Organizational Structure: Types

30:56
Organizational Structure: Product Strategies

30:55
Organizational Structure: Process & Product Organization

29:13
Organizational Structure and Culture

33:47
Organizational Structure: Principles

27:23
Plant Location & Layout: Selection of Site

39:56
Plant Location & Layout: Factor Affecting Selection of Site

32:53
Plant Location & Layout: Methods for Selection of Site

29:58
Plant Location & Layout: Methods for Selection of Site II

31:01
Plant Location & Layout: Methods for Selection of Site III

28:23
Plant Location & Layout: Methods for Selection of Site IV

30:36
Plant Layout: Purpose and Types of Layout

33:28
Plant Layout: Types of Layout

29:58
Plant Layout: Cellular and Process Layout

29:19
Plant Layout: Process Layout Design

34:20
Plant Layout: Process Layout Design II

34:10
Plant Layout: Product Layout Design

38:25
Organization of Facility

29:26
Organization of Facility & Material Handling

36:46
Material Handling

34:01
Production Planning and Control: Scope

29:19
Production Planning and Control: Scope II

31:14
Production Planning and Control: Capacity Planning

30:04
Production Planning and Control: Capacity Planning & Scheduling

26:44
Production Planning and Control: MRP, Routing, Scheduling

30:14
Production Planning and Control: Scheduling

32:17
Production Planning and Control: Priority Sequencing

31:32
Production Planning and Control: Priority Sequencing II

26:37
Production Planning and Control: Relative Performance of Priority Sequencing Rules

35:09
Inventory: Fundamentals

29:13
Inventory: Models

31:26
Inventory: Models II

37:11
Inventory: Wilson Model

33:12
Inventory: Gradual Replenishment Model

32:43
Project Management & Network Modelling: Introduction

33:00
Network Modelling: PERT

32:09
Network Analysis: PERT

47:41
Network Analysis: PERT II

29:21
Network Analysis: Crashing Network and CPM

34:01
Network Analysis: Critical Path Method

35:32
Forecasting: Introduction

32:16
Forecasting: Methods

31:41
Forecasting: Methods II

32:03
Forecasting: Methods III

31:31
Forecasting: Methods IV

31:19
Forecasting: Methods V

31:06
Quality Control: Introduction

32:11
Quality Control: Fundamentals

37:59
Quality Control: SPC

28:23
Quality Control: SPC II

29:30
Quality Control: Control Charts

30:06
Quality Control: Control Charts II

37:03
Quality Control: Control Charts for Attributes

35:25
Productivity & Work Study

31:53

Fundamentals of manufacturing processes

Understanding Manufacturing

29:30
Fundamental Approaches of Manufacturing

33:55
Manufacturing process Specific advantages and limitations

41:22
Material and Manufacturing Processes

32:43
Classification of Manufacturing Processes

27:34
Selection of Manufacturing Processes

32:41
Applications of Manufacturing Processes

33:30
Effect of Manufacturing Process on Mechanical properties

33:12
Break Even Analysis in Manufacturing Processes

32:30
Casting: Introduction and Suitability

35:46
Steps of Casting Processes

26:29
Casting: Terminology

40:13
The Pattern Allowances I

34:16
The Pattern Allowances II

31:10
Casting: Sand Moulding l

31:29
Sand Moulding II

38:12
Casting: Core and Core Prints

36:35
Casting: Gating System

38:54
Casting: Yield and Riser Design

31:04
Casting: Riser Design

25:32
Casting: Cleaning of Castings

29:59
Casting Casting Defects and their Preventions

42:12
Casting: Shell Mould Casting

29:56
Casting: Investment and Permanent Mould Casting

28:10
Metal Working Processes: Hot & Cold Working

32:04
Metal Working Processes: Rolling

36:48
Metal Working Processes: Forging

38:41
Metal Working Processes: Extrusion

32:26
Metal Working Processes: Wire Drawing

31:44
Metal Working Processes: Press

32:11
Sheet Metal Operations: Shearing

30:35
Metal Working Processes: Sheet Metal Operations II

33:15
Metal Working Processes: Sheet Metal Operations III

38:31
Metal Working Processes: Dies and Die sets

36:12
Material Removal Processes: Machining

37:09
Material Removal Processes: Mechanism of Metal Cutting

30:44
Material Removal Processes: Chip Formation

24:41
Material Removal Processes: Types of Chips and Power Consumption

33:08
Material Removal Processes: Heat Generation

27:45
Material Removal Processes: Tool Failure and Tool Life

31:55
Material Removal Processes: Tool materials

38:02
Material removal processes: Cutting fluids

32:58
Material removal processes: Grinding I

32:54
Material removal Processes: Grinding II

30:17
Material removal Processes: Grinding III

34:07
Material removal processes: Grinding operations

26:40
Joining of metals: Fundamentals I

28:08
Joining of metals: Fundamentals II

40:37
Joining of metals: Welding processes

28:32
Brazing, soldering and weldability

28:53
Weldability and welding defects

31:46
Heat treatment: Fundamentals I

30:57
Heat treatment: Fundamentals II

29:33
Heat treatment: Fundamentals III

40:50
Heat treatment: Normalizing and hardening

30:35
Heat treatment: Tempering

24:30
Improving surface properties: Introduction

28:52
Improving surface properties: Surface modification processes

28:00
Improving surface properties: Changing chemical composition

33:37
Improving surface properties: Coating

32:25

Mechanics of Machining

Metal Cutting And Machine Tools

Machining and Machine Tool Operations

Metrology and Inspection

Computer Integrated Manufacturing

Introduction to CIM

36:20
Introduction to CIM (Contd.)

23:58
Peuduction System

27:30
Automation in Manufacturing System

25:20
Automation Principles and Computer Aided Technologies

28:11
Computer Graphics (1 of 4)

32:49
Computer Graphics (2 of 4)

29:07
Computer Graphics (3 of 4)

31:34
Computer Graphics (4 of 4)

36:17
Geometric Modelling (part 1 of 2)

42:26
Geometric Modelling (part 2 of 2)

34:29
Computer Numerical Control (part 1 of 4)

27:22
Computer Numerical Control (part 2 of 4)

39:13
Computer Numerical Control (part 3 of 4)

01:01:11
Computer Numerical Control (part 4 of 4)

28:24
CNC Machining Centre (part 1 of 2)

26:53
CNC Machining Centre (part 2 of 2)

14:07
CNC Tooling

36:04
CNC Part Programming (part 1 of 4)

32:47
CNC Part Programming (part 2 of 4)

33:55
CNC Part Programming (part 3 of 4)

21:45
CNC Part Programming (part 4 of 4)

29:48
Laboratory Demonstration, Computer Aided Design (part 1 of 2)

54:08
Laboratory Demonstration, Computer Aided Design (part 2 of 2)

31:58
CAM Softwares

18:22
Laboratory Demonstration, CAM Softwares

55:52
Laboratory Demonstration, CNC Machining

23:39
Group Technology and Computer Aided Process Planning

54:54
Computer Aided Process Planning (part 1 of 2)

47:16
Computer Aided Process Planning (part 2 of 2)

01:02:59
Flexible Manufacturing System

57:41
Industrial Robotics

54:15
Programming Logical Controller

54:35
Automatic Identification and Data Capture

40:01
Computer Aided Quality Control (part 1 of 2)

41:49
Computer Aided Quality Control (part 2 of 2)

42:42
Laboratory Demonstration, Co-ordinate Measuring Machine

58:12
Rapid Manufacturing (part 1 of 2)

29:38
Rapid Manufacturing (part 2 of 2)

33:07
Laboratory Demonstration, Rapid Manufacturing (part 1 of 2)

40:25
Laboratory Demonstration, Rapid Manufacturing (part 2 of 2)

51:03
Laboratory Demonstration, CAD using Fusion 360, an Introduction

52:33
Laboratory Demonstration, CAD using Fusion 360, Rendering and 3D Printing

44:31
Material Handling Identification

01:01:33
Laboratory Demonstration, Plant Simulation Software (part 1 of 3)

23:06
Laboratory Demonstration, Plant Simulation Software (part 2 of 3)

48:19
Laboratory Demonstration, Plant Simulation Software (part 3 of 3)

37:54
Computers in Manufacturing Industry, Current Scenario (part 1 of 3)

57:18
Computers in Manufacturing Industry, Current Scenario (part 2 of 3)

43:41
Computers in Manufacturing Industry, Current Scenario (part 3 of 3)

47:15

Production and Operation Management

Introduction to Production

34:54
Global Environment

32:38
Operations and Productivity

32:14
Types and Characteristics of Manufacturing Systems

34:14
Types And Characteristics Of Services Systems

36:22
Product Design

36:14
Introduction To Forecasting

35:56
Time Series Forecasting

32:56
Time Series Forecasting- Exponential Smoothing I (Brief)

31:58
Time Series Forecasting- Exponential Smoothing II (Classification)

32:05
Time Series Forecasting- Working Example Of Exponential Smoothing I

32:46
Time Series Forecasting- Working Example Of Exponential Smoothing II

33:41
Time Series Forecasting- Working Example Of Exponential Smoothing III

29:53
Forecasting Errors

32:28
Causal Or Explanatory Methods

34:49
Inventory Planning and control

34:10
Basic Inventory Model

32:55
Different Variations in Basic EOQ Model

32:00
Safety Stock and Fixed Time Inventory Model

35:52
Examples of Safety Stock Calculation

36:13
Single Period Inventory Model-I (Theory)

33:01
Single Period Inventory Model-II (Numerical)

33:00
Inventory Control and Management

35:07
Material Requirements Planning (MRP)

35:45
Improvements in the MRP system

35:36
Lot Sizing in MRP Systems

36:27
Material Requirements Planning (MRP): Examples-I

31:50
Material Requirements Planning (MRP): Examples-II

33:32
Aggregate Sales and Operations Planning-I (Intermediate & Aggregate Planning)

29:22
Aggregate Sales and Operations Planning-II (Demand & Supply Options)

36:19
Aggregate planning Techniques-I (Introduction)

35:16
Aggregate planning Techniques-II (Examples)

31:54
Aggregate planning Techniques-III (Problems)

30:41
Production Planning Problems using LP

41:00
Nature of Quality and Evolution of Quality Management-I (Product Quality Dimensions)

33:35
Nature of Quality and Evolution of Quality Management-II (Service Quality Dimensions)

33:41
Modern Quality Management and Total Quality Management

32:25
Total Quality Management

37:30
Statistical Concepts in Quality Control-I (Overview of Control Charts)

32:29
Statistical Concepts in Quality Control-II (p-chart & Examples)

33:03
Statistical Concepts in Quality Control-III (c-chart & Examples)

30:56
Statistical Concepts in Quality Control-IV (Run Test & Examples)

36:06
7 QC Tools

36:02
Acceptance Sampling

42:30
Process Capability

39:30
Some Current Issues In Quality Management

36:58
Facility Layout-I (Introduction)

34:27
Facility Layout-II (Group Technology and other layouts)

40:40
Facility Layout-III (Layout design and Precedence diagram)

39:34
Introduction to Project Management

32:11
PERT and CPM

37:30
PERT and Crashing

37:26
Maintenance Management

40:25
Maintenance Performance Measures and OEE calculations

38:49
Manufacturing Operations Scheduling-I (Scheduling & Gantt Charts)

32:31
Manufacturing Operations Scheduling-II (Order Sequencing)

45:41
JIT and Lean Operations

34:26
Work Method Analysis, Work Measurement and Learning Curve

38:33
Some Latest and Future Issues

36:45
Six Sigma

32:25

Operations Management

Operations Management: Basics

32:19
Operations Management: Objectives

32:35
Operations Management: Functions and Scope

32:05
Types of Production Systems

34:12
Operations Strategy

34:15
Product Life-Cycle

30:40
Value Engineering Concepts

33:00
Design for X (DFX)

33:29
Ergonomics in Product Design

37:12
Rapid Prototyping: Concept, Advantages

32:43
Sales Forecasting

34:08
Forecasting System

36:33
Qualitative Methods of Forecasting

32:19
Quantitative Methods-I

42:26
Quantitative Methods-II

32:52
Facility Planning

32:09
Factors Affecting Plant Location

35:37
Plant Location: Case Study on Uttarakhand

27:29
Location Evaluation Methods-I

29:07
Location Evaluation Methods-II

30:31
Facility Layout and Planning-I

33:48
Facility Layout and Planning-II

36:45
Factors Influencing Plant Layout

34:57
Material Flow Patterns

32:43
Tools and Techniques used For Plant Layout Planning

33:10
Production Planning and Control

30:23
Process Planning

37:20
Aggregate Production Planning

38:20
Capacity Planning: Introduction

32:28
Capacity Planning: Examples

35:19
Project Scheduling

26:36
Network Diagrams

32:56
Critical Path Method

33:01
Critical Path Method: Problems-I

30:46
Critical Path Method: Problems-II

28:03
Program Evaluation and Review Technique (PERT)

29:48
PERT Problems-I

31:23
PERT Problems-II

31:03
Time Cost Trade Off (Crashing)

28:53
Project Network: Crashing Problems

37:04
Production Control

30:52
Sequencing

32:24
Sequencing Problems-I

34:42
Sequencing Problems-II

34:28
Master Production Scheduling (MPS)

29:55
Concept of Quality

32:04
Total Quality Management (TQM)

31:19
Total Productive Maintenance

28:04
Statistical Quality Control (SQC)

31:32
Six Sigma

32:11
Materials Management

26:46
Inventory Control

32:24
Economic Order Quantity (EOQ) Models

27:39
Economic Order Quantity (EOQ): Problems

29:15
Production Quantity Model

34:54
Just In time (JIT)

30:57
Kanban System

28:07
Materials Requirement Planning (MRP)-I

33:27
Materials Requirement Planning (MRP)-II

31:23
Enterprise Resource Planning (ERP)

29:44

Mechanical Engineering Preparation

About Course

What Will You Learn?

Course Content

Engineering Mechanics

Introduction to Vectors

Addition and subtraction of vectors

Multiplying vectors

Introduction to vectors: solved examples I

Introduction to vectors: solved examples II

Transformation of vectors under rotation

Vector products and their geometric interpretation

Vector Product: Kronecker Delta and Levi-Civita symbols-I

Vector Product: Kronecker Delta and Levi-Civita symbols-II

Equilibrium of rigid bodies – Forces and torques

Calculating torques and couple moments – I

Calculating torques and couple moments – II

Finding a force and a couple equivalent to an applied force

Different elements and associated forces and torques – I

Different elements and associated forces and torques – II

Solved examples; equilibrium of bodies – I

Solved examples; equilibrium of bodies – II

Forces in different geometric configurations

Plane trusses I – Building a truss and condition for it to be statically determinate

Plane trusses II – Calculating forces in a simple truss and different types of trusses

Plane trusses III – Calculating forces in a simple truss by method of joints

Plane trusses IV – Solved examples for calculating forces in a simple truss by method of joints

Plane trusses V – Solved examples for calculating forces in a simple truss by method of joints

Plane trusses VI: Method of sections for calculating forces in a simple truss

Dry friction I – introduction with an example

Dry friction II – a solved example

Dry friction III – Dry thrust bearing and belt friction with demonstration

Dry friction IV – Screw friction and rolling friction

Dry friction V: Solved examples

Properties of plane surfaces I – First moment and centroid of an area

Properties of plane surfaces II – Centroid of an area made by joining several plane surfaces

Properties of plane surfaces III – Centroid of a distributed force and its relation with centre…

Properties of plane surfaces IV – solved examples of calculation of first moment and centroid…

Properties of plane surfaces V- Second moment and product of an area and radius of gyration

Properties of plane surfaces VI – Parallel axis transfer theorem for second moment

Properties of plane surfaces VII – transformation of second moment and product of an area under rota

Properties of plane surfaces VIII – second moment and product of an area, solved examples

Method of virtual work I – degrees of freedom, constraints and constraint forces

Method of virtual work II – virtual displacement, virtual work and equilibrium condition

Method of virtual work III – solved examples

Motion of a particle in a plane in terms of planar polar coordinates

Planar polar coordinates: solved examples

Description of motion in cylindrical and spherical coordinate systems

Using planar polar, cylindrical and spherical coordinate systems: solved examples

Motion with constraints, constraint forces and free body diagram

Motion with constraints – solved examples

Motion with dry friction – solved examples

Motion with drag – solved examples

Equation of motion in terms of linear momentum and the principle of conservation of linear momentum

Linear momentum and centre of mass

Momentum transfer, impulse and force due to a stream of particles hitting an object

Momentum and the variable mass problem

Linear momentum – solved examples

Work and energy I – work energy theorem; conservative and non-conservative force fields

Work and energy II – Definition of potential energy for conservative forces; total mechanical energy

Work and energy III – Two solved examples using conservation principles

Work and energy IV – Further discussion on potential energy

Work and energy V – Solved examples

Work and energy VI – Applying conservation principles to solve a collision problem

Work and energy VII – Solved examples

Rigid body motion I – degrees of freedom and number of variables required to describe motion

Rigid body motion II – Equation of motion for a single particle in terms of angular momentum

Rigid body motion III – Conservation of angular momentum; angular momentum for a collection

Rigid body motion IV – applying angular momentum conservation, a solved example

Rigid body motion V (fixed axis rotation) – some demonstrations of conservation of angular momentum

Rigid body motion VI (fixed axis rotation) – Some more demonstrations and related problems

Rigid body motion VII (fixed axis rotation) – Kinetic energy and moment of inertia for fixed axis

Rigid body motion VIII (fixed axis rotation) – solved examples for calculating moment

Rigid body motion –IX (fixed axis rotation): solved examples

Rigid body motion X – rotation and translation with axis moving parallel to itself

Rigid body motion XI – solved examples for rotation and translation

Rigid-body dynamics XII – Some demonstrations on general motion of rigid bodies

Rigid-body dynamics XIII – Infinitesimal angles as vector quantities and change of a vector

Rigid-body dynamics XIV – Angular velocity and the rate of change of a rotating vector

Rigid-body dynamics XV – Relationship between angular momentum and angular velocity