UKA Tarsadia University Faculty of Technology and Engineering

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UKA Tarsadia University

Faculty of Technology and Engineering


B.

Tech.


1
st
Sem


0300
6
0106
-

MECHANICS

OF SOLIDS



Syllab
us
:



A. Objective of the Course

Objectives of introducing this subject at first year level in all the branches are:



To study about
identification of different types of forces, systematic evaluation of effect
of these forces, behavior of rigid bodies subjected to various types of forces, at the state
of rest or motion of the particles, as Universe exist due to force only.



To unde
rstand

the fundamental principal
, concepts and techniques, both theoretical and
experimental, with emphasis on the application of these to the solution of mechanics
based suitable problems in all engineering.



To provide a firm foundation and formwork for more ad
vanced study at every higher
semester as the subject of Mechanics of Rigid bodies cuts broadly across all branches of
engineering profession.



B. Outline of the C
ourse:

Sr.No.

Title of the Modules

Minimum number
of hours

Theory

Practical

1

Fundamental of
S
tatics

1
2

06

2

C
entre of
G
ravity
and
Moment of Inertia

10

04

3

Friction

0
6

04

4

Truss

05

02

5

Introduction to
D
ynamics
, Vibration and Simple
Stresses & Strains

1
2

10

6

Beams & Principal Stresses and Strain

1
5

0
4


Total Hours

60

30


Total Hours (Theory
)+(
Practic
al
)

90




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C. Detailed Syllabus






Sr.
No.

Topic name

W
eight age

(%)

1
.

Fundamental of Statics


20

1.1

1.2

1.3

1.4

1.5

1.6

1.7

1.8

1.9

1.10

1.11

1.12

S
calar and V
ector quantities laws of mechanics & system of
units

Composition and resolution of vector fundamental concepts
and idealization of mechanics

Force, force systems and resultant

Composition and
resolution of force

Resultant of concurrent force systems

Concepts of moment & couple

Resultant of non
-
concurrent force systems

Equilibrant, equilibrium of forces

Resultant of spatial force system

Equilibrium of particle & rigid body


2.

C
entre of
G
ravity
and Moment of Inertia

1
0

2.1

C
oncept of centre of gravity, centre of mass & centroid


2.2

C
entroid lines, plane areas of volumes and bodies


2.3

P
appus
-
guldinus theorems


2.4

M
oment of inertia


3.

Beams

&
Principal Stresses and Strain

20

3.1

3.2

3.3

3.4

3.5


3.6

3.7

SF and BM Diagram

Bending Stress Distribution in beams

Shear Stress Distribution in beams

Compound Stresses

Analysis of principal plane and principal stresses of angle of
obliquity of resultant stress

Principal Strain

Principal
Stress in beam


3.

Friction


10

3.1

Friction, types and its applications


3.2

Simple frictionless rigid body assemblies


3.3

Rigid body assemblies including friction


4
.

Truss

10

4.1

Classification of truss, perfect & imperfect truss


4.2

Analysis of pin
-
jointed perfect truss using method of joints &
method of section



5
.

Introduction to Dynamics, Vibration and Simple Stresses
& Strains

30

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4


5.1


5.2


5.3


5.4

5.5


5.6

Kinematics of particle: concept of rectilinear motion, circular
motion, projectile &compound motion

Kinetics of particle: Newton’s 2 law, dynamic
equilibrium,
energy and momentum methods

Types of vibrations, free, forced, damping and de
-
Alembert’s
princip
al

Application of single degree of freedom system

Simple stress & strain: tensile, compressive, shear,
temperature, hoop stresses

Physical &
mechanical properties metals: ductility, britlity,
harness, toughness, malleability






D. Instructional Method and Pedagogy:



At the start of course, the course delivery pattern, prerequisite of the subject will be
discussed.



Lectures will be also
conducted with the aid of multi
-
media projector, black board, OHP
etc.



Attendance is compulsory in lectures and laboratory which carries a 5% component of
the overall evaluation.



Minimum two internal exams will be conducted and average of two will be consi
dered as
a part of 15% overall evaluation.



Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval. It carries a weightage
of 5
%.



Surprise tests will be conducted which carries 5% of the overall evaluation.



The course includes a laboratory, where students have an opportunity to build an
appreciation for the concepts being taught in lectures.



Minimum 8 experiments shall be there in
the laboratory related to course contents.



Minimum 6 tutorials which includes solution of minimum 5 numerical under each head.


E. Student Learning Outcomes



On the completion of the course one should be able to understand:



Students will able to understand

the laws of mechanics and their application to engineering
problem.



Student will be able to understand the fundamentals of stress/strain analysis and be able to
apply them with confidence to simple structure.



Fundamental related to subject will facilitate

students to design structures, predict failure
and understand the physical properties of materials in higher semester.




F. Recommended Study Material
:

a) Text Books:



Beer and Johnston
-

Mechanics of Materials


TMH

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4

of
4






b) Reference B
ooks:




G
. S.
Sawhney
-

Engineering Mechanics
-

PHI New Delhi



S. B. Junarkar & H. J. Shah
-

Applied Mechanics
-

Charotar Publication




Gere & Timoshenko
-
Mechanics of Materials
-

CBS Publishers & Distributors, Delhi



Hibbler R C
-

Mechanics of Materials
-

Pearson Education



Popov E.P
-

Engineering Mechanics of Solids
-

Prentice Hall of India, New Delhi



J. L. Meriam, L. G. Kraige. John wiley & Son
-

Engineering Mechanics Statics
-

Singapore.



Desai & Mistry
-

Engineering Mechanics
-

Popular Prak
a
shan



S.G. Shah,
S. G. Shah

& Gop
al N. Shah

-

Mechanics of solids
-

Superior publication


b) Web Links:




www.physics
forum.com



www.
nptel
.ii
t
m.ac.in