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Engineering Mechanics Syllabus

This document outlines a lesson plan for an Engineering Mechanics course taught during the second semester of 2015. The course will be taught over 40 contact hours across 4 days per week by Mrs. Sunita Singh Naik. The course is divided into 4 modules covering topics such as forces, equilibrium, plane trusses, momentum, kinematics, and rotation of rigid bodies. Recommended textbooks and reference materials are also listed.

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Raja Ramachandran
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63 views2 pages

Engineering Mechanics Syllabus

This document outlines a lesson plan for an Engineering Mechanics course taught during the second semester of 2015. The course will be taught over 40 contact hours across 4 days per week by Mrs. Sunita Singh Naik. The course is divided into 4 modules covering topics such as forces, equilibrium, plane trusses, momentum, kinematics, and rotation of rigid bodies. Recommended textbooks and reference materials are also listed.

Uploaded by

Raja Ramachandran
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
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Download as PDF, TXT or read online on Scribd
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VEER SURENDRA SAI UNIVERSITY OF TECHNOLOGY

LESSON PLAN
Semester >>2nd Year >> 2015 Contact Hours per week >>4

Branch >>
Total Credit >>4
ENGINEERING
Metallurgical & Materials DAY
MECHANICS
Engineering Monday, Thursday,Friday,Saturday
TEACHER Mrs Sunita Singh Naik
Period Jan 2015-April 2015
Recommended
Text book:
books >>
1. Engineering mechanics: S Timoshenko & Young; 4th Edition (international
edition) MC Graw Hill.

Reference books:

1. Fundamental of Engineering mechanics (2nd Edition): S Rajesekharan& G


ShankaraSubramanium; Vikas Pub. House Pvt ltd.
2. Engineering mechanics: K.L. Kumar; Tata MC Graw Hill.

Sl. Lecture No. Topics to be covered


No.
MODULE -I
Lecture-01
1 Introduction of Engineering Mechanics,Types of forces

2 Lecture-02 System of forces: Concurrent & Coplanar forces


3 Lecture-03 Composition of forces:Parallelogram law, Triangle law & Polygon law
Lecture-04 Resolution of forces, law of transmissibility, law of Superposition, Free Body
4 Diagram

5 Lecture-05 Equilibrium of concurrent coplanar forces, Lami’s theorem


6 Lecture-06 Method of projection
7 Lecture-07 Problem solving
8 Lecture-08 Method of moment, basic theory and numericals
9 Lecture-09 Friction: Types, Basic theory
10 Lecture-10 Related numericals of friction
11 Lecture-11 Parallel forces on a plane ,General case of parallel forces
12 Lecture-12 Center of parallel forces and center of gravity: Pappus theorem
13 Lecture-13 Centroid of composite plane figure and curves & related problems
MODULE -II
Lecture-14
Composition and equilibrium of forces in a plane
14

15 Lecture-15 Plane trusses:Basic theory


16 Lecture-16 Problems using Method of joints
Lecture-17 Problems using Method of sections
17
18 Lecture-18 Principle of virtual work: Basic theory
19 Lecture-19 Numericals related to Virtual work
Lecture-20 Moment of inertia: Plane figure with respect to an axis in its plane and perpendicular
20
to the plane
21 Lecture-21 Perpendicular axis theorem & related problems
22 Lecture-22 Parallel axis theorem & related problems
23 Lecture-23 Doubt clearing class

MODULE-III
Lecture-24 Rectilinear Translation: Kinematics, Principle of dynamics
24
25 Lecture-25 D Alembert’s Principle Basic theory and numericals
26 Lecture-26 Impulse and Momentum: Basic theory and numericals
27 Lecture 27 Work and energy, Conservation of Energy, Basic theory and problems
28 Lecture 28 Impact: types, coefficient of restitution
29 Lecture 29 Basic theory and numericals related to impact
MODULE-IV
30 Lecture 30 Curvilinear translation: Kinematics, Equation of motion
31 Lecture 31 Moment & Momentum
32 Lecture 32 Projectile motion Basic theory
33 Lecture 33 Numerical related to projectile
34 Lecture-34 D Alembert’s principle of curvilinear motion
35 Lecture-35 Kinematics of rotation of rigid body
36 Lecture-36 Numerical Problem related to rotation of rigid body
37 Lecture-37 Class-Test
38 Lecture -38 Brief Review & discussion
39 Lecture -39 Revision & Clarification of Doubts
40 Lecture -40

Signature of Teacher

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