5 year-inhtegrated dual degree (b.tech + m.tech) (1)
TRANSCRIPT
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GITAM UNIVERSTIY (Declared as Deemed to be University U/S 3 of UGC Act, 1956)
REGULATIONS & SYLLABUS
Of
Five Year Dual Degree (B.Tech +M.Tech)
Mechanical Engineering (W.e.f 2010-11 admitted batch)
Gandhi Nagar Campus, Rushikonda
VISAKHAPATNAM – 530 045 Website: www.gitam.edu
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REGULATIONS (w.e.f. 2010-11 admitted batch)
1.0 ADMISSIONS
1.1 Admissions into Five year Dual Degree (B.Tech. + M.Tech) programme in
Mechanical Engineering of GITAM University are governed by GITAM
University admission regulations.
2.0 ELIGIBILTY CRITERIA
2.1 A minimum of 60% marks aggregate in Physics, Chemistry and Mathematics and
First class or equivalent grade in 10+2 or equivalent examination approved by
GITAM University in single attempt.
2.2 Admissions into Five year Dual Degree (B.Tech. + M.Tech) programme will be
based on an All India Entrance Test (GAT) conducted by GITAM University and
the rule of reservation, wherever applicable.
3.0 STRUCTURE OF FIVE YEAR DUAL DEGREE (B.Tech. + M.Tech.)
PROGRAMME
3.1 The Programme of instruction consists of:
(i) A general core programme comprising Basic Sciences, Basic Engineering,
Humanities & Social Sciences and Mathematics.
(ii) An engineering core programme imparting to the student the fundamentals
of engineering in the branch concerned.
(iii) The electives of the programme from V Semester onwards enabling the
students to take up a group of specialized courses.
(iv) A specialization for M.Tech. can be opted by the students from the
specialized groups offered by the Department.
(v) The M.Tech. specialization of the student shall be decided on the merit
based choice.
In addition, a student has to
(i) carry out two technical projects in VIII and X semesters approved by the
Department and submit a report.
(ii) undergo internship / industrial training in an industry for a period of 12
weeks and submit a report.
3.2 Each academic year consists of two semesters. Five year Dual Degree (B.Tech. +
M.Tech) programme in Mechanical Engineering has a curriculum and course content
(syllabi) for the courses recommended by the Board of Studies concerned and
approved by Academic Council.
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4.0 CREDIT BASED SYSTEM
4.1 Each course is assigned certain number of credits which will depend upon the
number of contact hours (lectures & tutorials) per week.
4.2 In general, credits are assigned to the courses based on the following contact
hours per week per semester.
One credit for each Lecture / Tutorial hour.
One credit for two hours of Practicals.
Two credits for three (or more) hours of Practicals.
4.3 The curriculum of Five year Dual Degree (B.Tech. + M.Tech) programme in
Mechanical Engineering is designed to have a total of 235 credits for the award
of B.Tech + M.Tech. degree.
5.0 MEDIUM OF INSTRUCTION
The medium of instruction (including examinations and project reports) shall be English.
6.0 REGISTRATION
Every student has to register himself/herself for each semester individually at the time
specified by the Institute / University.
7.0 CONTINUOUS ASSESSMENT AND EXAMINATIONS
7.1 The assessment of the student‟s performance in each course will be based on
continuous internal evaluation and semester-end examination. The marks for
each of the component of assessment are fixed as shown in the Table 2.
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Table 1: Assessment Procedure S.No. Component of
assessment Marks allotted Type of
Assessment Scheme of Examination
1
Theory
Total
40
Continuous
evaluation
(i) Two mid semester
examinations shall be
conducted for 10 marks each.
(ii) Two quizzes shall be
conducted for 5 marks each.
(iii) 5 marks are allotted for
assignments.
(iv) 5 marks are allotted for
attendance
60
Semester-end
examination
The semester-end examination
in theory courses will be for a
maximum of 60 marks.
100
2
Practicals
100
Continuous
evaluation
(i) 40 marks are allotted for
record work and regular performance of the student in
the lab.
(ii) One examination for a
maximum of 20 marks shall be
conducted by the teacher
handling the lab course at the
middle of the semester
(iii) One examination for a
maximum of 40 marks shall be
conducted at the end of the
semester (as scheduled by the Head of the Department
concerned).
3
Project work
100
Project evaluation
(i) 50 marks are allotted for
continuous evaluation of the
project work throughout the
semester by the guide.
(ii) 50 marks are allotted for the
presentation of the project work
& viva-voce at the end of the
semester.*
4
Internship /
Industrial Training
100
Internship /
Industrial training
evaluation
(i) 50 marks are allotted for
report submission and seminar presentations after completion
of the training.
(ii) 50 marks are allotted for the
viva-voce at the end of the
semester.*
* Head of the Department concerned shall appoint two examiners for conduct of the
examination.
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8.0 RETOTALLING, REVALUATION & REAPPEARANCE
8.1 Retotalling of the theory answer script of the end-semester examination is permitted
on a request made by the student by paying the prescribed fee within ten days of the
announcement of the result.
8.2 Revaluation of the theory answer script of the end-semester examination is also
permitted on a request made by the student by paying the prescribed fee within fifteen
days of the announcement of the result.
8.3 A Student who has secured „F‟ Grade in any theory course / Practicals of any
semester shall have to reappear for the semester end examination of that course /
Practicals along with his / her juniors.
8.4 A student who has secured „F‟ Grade in Project work / Industrial Training shall have
to improve his report and reappear for viva – voce Examination of project work at the
time of special examination to be conducted in the summer vacation after the last
academic year.
9.0 SPECIAL EXAMINATION
9.1 A student who has completed the stipulated period of study for the degree
programme concerned and still having failure grade („F‟) in not more than 5
courses ( Theory / Practicals), may be permitted to appear for the special
examination, which shall be conducted in the summer vacation at the end of the
last academic year.
9.2 A student having „F‟ Grade in more than 5 courses (Theory/practicals) shall not
be permitted to appear for the special examination.
10.0 ATTENDANCE REQUIREMENTS
10.1 A student whose attendance is less than 75% in all the courses put together in any
semester will not be permitted to attend the end - semester examination and he/she
will not be allowed to register for subsequent semester of study. He /She has to repeat
the semester along with his / her juniors.
10.2 However, the Vice Chancellor on the recommendation of the Principal / Director of
the University College / Institute may condone the shortage of attendance to the
students whose attendance is between 66% and 74% on genuine medical grounds and
on payment of prescribed fee.
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11.0 GRADING SYSTEM
11.1 Based on the student performance during a given semester, a final letter grade will
be awarded at the end of the semester in each course. The letter grades and the
corresponding grade points are as given in Table 3.
Table 2: Grades & Grade Points
11.2 A student who earns a minimum of 5 grade points (C grade) in a course is
declared to have successfully completed the course, and is deemed to have earned
the credits assigned to that course. However, a minimum of 24 marks is to be
secured at the semester end examination of theory courses in order to pass in the
theory course.
12.0 GRADE POINT AVERAGE
12.1 A Grade Point Average (GPA) for the semester will be calculated according to the
formula:
Σ [ C x G ]
GPA = ----------------
Σ C
Where
C = number of credits for the course,
G = grade points obtained by the student in the course.
12.2 Semester Grade Point Average (SGPA) is awarded to those candidates who pass
in all the courses of the semester.
12.3 To arrive at Cumulative Grade Point Average (CGPA), a similar formula is used
considering the student‟s performance in all the courses taken in all the semesters
completed up to the particular point of time.
Grade Grade points Absolute Marks
O 10 90 and above
A+ 9 80 – 89
A 8 70 – 79
B+ 7 60 – 69
B 6 50 – 59
C 5 40 – 49
F Failed, 0 Less than 40
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12.4 The requirement of CGPA for a student to be declared to have passed on successful
completion of the 5 year dual degree (B.Tech+M.Tech) programme and for the
declaration of the class is as shown in Table 4.
Table 3: CGPA required for award of Degree
Distinction ≥ 8.0*
First Class ≥ 7.0
Second Class ≥ 6.0
Pass ≥ 5.0
* In addition to the required CGPA of 8.0, the student must have necessarily passed all the
courses of every semester in first attempt.
13.0 ELIGIBILITY FOR AWARD OF THE B.Tech. + M.Tech. DEGREE
13.1 Duration of the programme:
A student is ordinarily expected to complete the Dual degree (B Tech.+ M.Tech.)
programme in ten semesters of five years. However a student may complete the
programme in not more than seven years including study period.
13.2 However the above regulation may be relaxed by the Vice Chancellor in
individual cases for cogent and sufficient reasons.
13.3 A student shall be eligible for award of the B.Tech + M.Tech. degree if he / she
fulfils all the following conditions.
a) Registered and successfully completed all the courses and projects.
b) Successfully acquired the minimum required credits as specified in the
curriculum corresponding to the branch of his/her study within the stipulated
time.
c) Has no dues to the Institute, hostels, Libraries, NCC / NSS etc, and
d) No disciplinary action is pending against him / her.
13.4 Two degrees will be awarded to students after successful completion of the
Programme- B.Tech & M.Tech.
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RULES
1. With regard to the conduct of the end-semester examination in any of the practical
courses of the programme, the Head of the Department concerned shall appoint one
examiner from the department not connected with the conduct of regular laboratory work,
in addition to the teacher who handled the laboratory work during the semester.
2. In respect of all theory examinations, the paper setting shall be done by an external paper
setter having a minimum of three years of teaching experience. The panel of paper setters
for each course is to be prepared by the Board of Studies of the department concerned
and approved by the Academic Council. The paper setters are to be appointed by the Vice
Chancellor on the basis of recommendation of Director of Evaluation / Controller of
Examinations.
3. The theory papers of end-semester examinations will be evaluated by internal/external
examiner.
4. Panel of examiners of evaluation for each course is to be prepared by the Board of
Studies of the department concerned and approved by the Academic Council.
5. The examiner for evaluation should possess post graduate qualification and a minimum
of three years teaching experience.
6. The appointment of examiners for evaluation of theory papers will be done by the Vice
Chancellor on the basis of recommendation of Director of Evaluation / Controller of
Examinations from a panel of examiners approved by the Academic Council.
7. Project – II in VIII semester shall be evaluated by two examiners at the semester end
examination. One examiner shall be internal and other examiner will be external. The
Vice-chancellor can permit appointment of second examiner to be internal when an
external examiner is not available.
8. The attendance marks ( maximum 5) shall be allotted as follows :
Percentage of
Attendance
Marks
76% to 80% 1
81% to 85% 2
86% to 90% 3
91% to 95% 4
96% to 100% 5
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Course structure
Five Year Dual degree (B. Tech + M.Tech)
Programme Code: EIRME201000
I Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIREG 101 ENGLISH WRITING SKILLS HS 3 3 40 60 100 3
EIRMT 102 ENGG. MATHEMATICS –I MT 4 4 40 60 100 4
EIRPH 103 ENGG. PHYSICS BS 4 4 40 60 100 4
EIRCH 104 ENVIRONMENTAL
STUDIES HS 3 3 40 60 100 3
EIRCS 105 PROGRAMMING WITH C BE 3 3 40 60 100 3
EIRME 106 GEOMETRICAL DRAWING BE 1 3 4 40 60 100 3
EIRCS 111 PROGRAMMING WITH C
LAB BE - - 3 3 100 -- 100 2
EIRPH 112 ENGINEERING PHYSICS
LAB BS 3 3 100 -- 100 2
EIRME 113
WORKSHOP TECHNOLOGY
LAB BE 3 3 100 -- 100 2
TOTAL 26
II Semester
Course
Code
Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRMT 201 ENGG. MATHEMATICS –II MT 3 1 4 40 60 100 3
EIRMT 202 ENGG. MATHEMATICS –III MT 3 1 4 40 60 100 3
EIRCH 203 ENGG. CHEMISTRY BS 4 4 40 60 100 4
EIRPH 204 MATERIAL SCIENCE BS 3 3 40 60 100 3
EIRME 205 ENGINEERING MECHANICS BE 3 1 4 40 60 100 4
EIRME 206 ENGINEERING ECONOMICS BE 3 3 40 60 100 3
EIRCH 211 ENGINEERING CHEMISTRY
LAB
BS - - 3 3 100
-- 100 2
EIREG212 ENGLISH LANGUAGE LAB HS 3 3 100 -- 100 2
EIRME 213 ENGINEERING GRAPHICS
LAB
BE 3 3 100
-- 100 2
TOTAL 26
10
III Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME301 MANUFACTURING
TECHNOLOGY – I CE 3
3 40 60 100 3
EIRME302 MECHANICS OF SOLIDS – I CE 2 1 3 40 60 100 3
EIRME303 APPLIED THERMODYNAMICS
– I CE 2 1
3 40 60 100 3
EIRME304 METALLURGY CE 3 3 40 60 100 3
EIRME305 FLUID MECHANICS CE 2 1 3 40 60 100 3
EIREE306 BASIC ELECTRICAL AND
ELECTRONICS ENGINEERING
BE 3 1 4 40 60 100 4
EIRME 311 MECH. ENGG. –I LAB CE 3 3 100 -- 100 2
EIRME 312 MANUFACTURING
TECHNOLOGY – I LAB CE 3 3 100 -- 100 2
EIREE 313 ELECTRICAL ENGINEERING
LAB BE 3 3 100 -- 100 2
EIRME 314 INDUSTRIAL TOUR IT -- -- NA
TOTAL 25
IV Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 401 INDUSTRIAL ENGINEERING
AND MANAGEMENT CE 3 3 40 60 100 3
EIRME 402 MANUFACTURING
TECHNOLOGY – II CE 3 3 40 60 100 3
EIRME 403 APPLIED THERMODYNAMICS –
II CE 2 1 3 40 60 100 3
EIRME 404 MECHANICS OF SOLIDS -II CE 2 1 3 40 60 100 3
EIRME 405 THEORY OF MACHINES-I CE 2 1 3 40 60 100 3
EIRME 406 HYDRAULIC MACHINERY AND
SYSTEMS CE 2 1 3 40 60 100 3
EIRME 411 MECH. ENGG. –II LAB CE 3 3 100 -- 100 2
EIRME MECHANICS OF SOLIDS LAB CE 3 3 100 -- 100 2
EIRME 413 MACHINE DRAWING CE 3 3 100 -- 100 2
TOTAL 24
11
V Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 501 THEORY OF MACHINES-II CE 2 1 3 40 60 100 3
EIRME 502 METROLOGY CE 3 3 40 60 100 3
EIRME 503 POWER PLANT
ENGINEERING CE 2 1 3 40 60 100 3
EIRME 504 MACHINE DESIGN CE 3 1 4 40 60 100 4
EIRME 505 INSTRUMENTATION AND
CONTROL SYSTEMS CE 2 1 3 40 60 100 3
EIRME 506 OPERATIONS RESEARCH CE 2 1 3 40 60 100 3
EIRME 511
FLUID MECHANICS &
HYDRAULIC MACHINERY
LAB
CE 3 3 100 -- 100 2
EIRME 512 MANUFACTURING
TECHNOLOGY-II LAB CE 3 3 100 -- 100 2
EIREG 513 ENGLISH COMMUNICATION
SKILLS LAB HS 3 3 100 -- 100 2
TOTAL 25
VI Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s L T P
Total
hours C S T
EIRME 601 COMPUTATIONAL
METHODS IN ENGINEERING CE 3 1 4 40 60 100 4
EIRME 602 HEAT AND MASS TRANSFER CE 2 1 3 40 60 100 3
EIRME 603 PRODUCTION PLANNING &
CONTROL CE 3 3 40 60 100 3
EIRME 604 CAD/CAM 3 1 4 40 60 100 4
EIRME 605 AUTOMOBILE
ENGINEERING CE 3 3 40 60 100 3
EIRME 611 PRODUCTION DRAWING
LAB CE 3 3 100 -- 100 2
12
EIRME 612 METROLOGY LAB CE 3 3 100 -- 100 2
EIRME 613 INDUSTRIAL ENGINEERING
LAB CE 3 3 100 -- 100 2
EIRME 614 PERSONALITY
DEVELOPMENT HS -- -- NA
TOTAL 23
Manufacturing Technology Specialization
VII Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 701 FINITE ELEMENT
ANALYSIS CE 3 1 4 40 60 100 4
EIRME 702M ROBOTICS AND ROBOT
APPLICATIONS CE 3 1 4 40 60 100 4
EIRME 703M FLEXIBLE
MANUFACTURING
SYSTEMS
3 1 4 40 60 100 4
EIRME 711 CAD/CAM LAB CE 3 3 100 -- 100 2
EIRME 712 HEAT AND MASS TRANSFER
LAB CE 3 3 100
-- 100 2
EIRME 713 INTERNSHIP CE
3 months during
(May, June, July) -- 100 100 8
TOTAL 24
VIII Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 801M METAL FORMING
TECHNIQUES CE 3 1 4 40 60 100 4
EIRME 802M ADVANCED
MANUFACTURING
PROCESSES
CE 3 1 4 40 60 100 4
EIRME 803M CNC MACHINES & PART
PROGRAMMING CE 3 1 4 40 60 100 4
EIRME 804 ELECTIVE – 1 CE 3 1 4 40 60 100 4
EIRME 811 PROJECT 1 CE 7 7 50 50 100 8
TOTAL 24
13
IX Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 901M ADVANCED OPTIMIZATION
TECHNIQUES CE 3 1 4 40 60 100 4
EIRME 902M COMPUTER AIDED
INSPECTION CE 3 1 4 40 60 100 4
EIRME 903M ELECTIVE – 2 CE 3 1 4 40 60 100 4
EIRME 904M ELECTIVE – 3 CE 3 1 4 40 60 100 4
EIRME 905 M ELECTIVE – 4 CE 3 1 4 40 60 100 4
EIRME 911M FINITE ELEMENT METHODS
LAB CE 3 3 60 40 100 2
TOTAL 22
X Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 1001 PROJECT-2 CE 50 50 100 16
TOTAL 16
EIRME 804 Elective – 1 Inter Departmental (Common with B.Tech Mechanical)
Sno Course Code Name of the Course
1 EIRME804A DATABASE MANAGEMENT SYSTEMS
2 EIRME804B ARTIFICIAL INTELLIGENCE IN MANUFACTURING
3 EIRME804C WEB TECHNOLOGY
4 EIRME804D DATA STRUCTURES
List of Electives in Manufacturing Stream
Code Name of the course
Elective-2
EIRME903MA RAPID PROTOTYPING AND VIRTUAL PROTOTYPING
EIRME903MB JOINING PROCESSES
EIRME903MC ADVANCED MATERIALS AND PROCESSING
Elective-3
EIRME904MA PRODUCTION MANAGEMENT
EIRME904MB MANAGEMENT INFORMATION SYSTEMS
EIRME904MC DESIGN OF EXPERIMENTS
Elective-4
EIRME905MA COMPUTER INTEGRATED MANUFACTURING
EIRME905MB MACHINE TOOL DESIGN
EIRME905MC DESIGN OF MATERIAL HANDLING SYSTEMS
14
Thermal Engineering Specialization
VII Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRMT 701 FINITE ELEMENT
ANALYSIS CE 3 1 4 40 60 100 4
EIRME 702T COMPUTATIONAL FLUID
DYNAMICS CE 3 1 4 40 60 100 4
EIRME 703T ADVANCED FLUID
MECHANICS 3 1 4 40 60 100 4
EIRME 711 CAD/CAM LAB CE 3 3 100 -- 100 2
EIRME 712 HEAT AND MASS
TRANSFER LAB CE 3 3 100
-- 100 2
EIRME 713 INTERNSHIP CE
3 months during
(May, June, July) --
100 100 8
TOTAL 24
VIII Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 801T ADVANCED HEAT &
MASS TRANSFER CE 3 1 4 40 60 100 4
EIRME 802T DESIGN OF THERMAL
EQUIPMENTS CE 3 1 4 40 60 100 4
EIRME 803T MODERN ENERGY
SYSTEMS
CE 3 1 4 40 60 100 4
EIRME 804 ELECTIVE – 1 CE 3 1 4 40 60 100 4
EIRME 811 PROJECT-1 CE 7 7 50 50 100 8
TOTAL 24
15
IX Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 901T ENERGY CONSERVATION
AND MANAGEMENT CE 3 1 4 40 60 100 4
EIRME 902T HEATING, VENTILATION
AND AIR CONDITIONING
& CRYOGENICS
CE 3 1 4 40 60 100 4
EIRME 903T ELECTIVE – 2 CE 3 1 4 40 60 100 4
EIRME 904T ELECTIVE – 3 CE 3 1 4 40 60 100 4
EIRME 905T ELECTIVE – 4 CE 3 1 4 40 60 100 4
EIRME911T COMPUTATIONAL FLUID
DYNAMICS LAB CE 3 3 60 40 100 2
TOTAL 22
X Semester
Course
Code Name of the Course
Cat
egory
Instruction hours per
week
Maximum
Marks
Cre
dit
s
L T P Total
hours C S T
EIRME 1001 PROJECT-2 CE 50 50 100 16
TOTAL 16
EIRME 804 Elective – 1 Inter Departmental (Common with B.Tech Mechanical)
List of Electives in Thermal Stream
Code Name of the course
Elective-2
EIRME903TA FUEL CELL TECHNOLOGY
EIRME903TB FLUDIZED BED SYSTEMS
EIRME903TC ADVANCED THERMODYNAMICS
Elective-3
EIRME904TA NUCLEAR ENGINEERING
EIRME904TB SOLAR ENERGY TECHNOLOGY
EIRME904TC THERMAL MEASUREMENTS
Elective-4
EIRME905TA THERMAL TURBO MACHINERY
EIRME905TB MULTIPHASE FLOW
EIRME905TC ADVANCED IC ENGINES
16
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EIREG 101: English Writing Skills
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
Topics Periods
Tenses 3
Concord 3
Error Analysis 2
Single Sentence Definitions 2
Paragraph Writing 2
Essay Writing 2
Dialogue Writing 1
Reading Comprehension 2
Note Making 2
Precis Writing 2
Features of Abstract 1
Characteristics of Technical Paper 1
Notices 1
Memo 2
Minutes of the Meeting 2
Letter Writing (Letter of Enquiry, Permission,
Regret, Reconciliation, Complaint)
3
Drafting Curriculum vitae 2
Resume and Covering Letter 2
Job Application 1
Total 36
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EIRMT 102: ENGINEERING MATHEMATICS – I
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
17
The objective of the course is to impart knowledge in Basic concepts of Mathematics relevant to
Engineering applications.
Unit - I.
Linear Differential Equations of Higher order
Definition, Complete solution, Operator D, Rules for finding complementary function, Inverse
operator, Rules for finding particular integral, Method of variation of parameters.
Unit-II
Equations reducible to Linear Differential Equations and Applications Cauchy‟s and Legendre‟s linear equations, Simultaneous linear equations with constant
coefficients and applications of linear differential equations to Oscillatory Electrical
circuits L-C, LCR – Circuits, Electromechanical Analogy.
Unit –III
Multiple Integrals and its Applications:
Double integrals, Change of order of integration, Double integrals in Polar coordinates, Areas
enclosed by plane curves, Triple integrals, Volume of solids, Change of variables, Area of a
curved surface.
Unit –IV
Special Functions and its Applications:
Beta function, Gamma function, Relation between beta and gamma functions, Dirichlet integrals
of type I and type II.
Unit-V
Infinite Series
Definitions of convergence, divergence and oscillation of a series, General properties of series,
Series of positive terms, Comparison tests, Integral test, D‟ Alembert‟s Ratio test, Raabe‟s test,
Cauchy‟s root test, Alternating series, Leibnitz‟s rule, Power series, Convergence of exponential,
Logarithmic and binomial series (without proofs).
Text Prescribed :
Higher Engineering Mathematics, Dr.B.S Grewal. Khanna
Publishers.
References :
Advanced Engineering Mathematics, Erwin Kreyszig. Wiley Eastern Pvt. Ltd.
Textbook of Engineering Mathematics, N.P.Bali. Laxmi Publications (P) Ltd.
Higher Engineering Mathematics, Dr.M.K.Venkata Raman. National Pub. Co.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EIRPH 103 ENGINEERING PHYSICS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
18
The aim of the course is to impart knowledge in Basic Concepts of Physics relevant to
Engineering applications.
.
UNIT – I
ELECTROMAGNETIC OSCILLATIONS AND ALTERNATING CURRENTS: Energy
Stored in a Capacitor and an Inductor - LC Oscillations (Qualitative and Quantitative) - Analogy
to Mechanical Motion-Damped Oscillations - Damped Oscillations in an RLC Circuit-
Alternating Current (Including Equations for Voltages and Currents) - Fundamental Definitions -
(Cycle, Time period, Frequency, Amplitude, Phase, Phase Difference, Root Mean Square (RMS)
value, Average Value, Form Factor, Quality Factor, Power in Alternating Current Circuits) -
Forced Oscillations and Resonance - The Series RLC Circuit.
ELECTROMAGNETIC WAVES: Induced Magnetic Fields - Displacement Current -
Maxwell‟s Equations- Traveling Waves and Maxwell‟s Equations - The Poynting Vector - Light
and the Electromagnetic Spectrum.
UNIT-II
DIELECTRIC PROPERTIES: Introduction - Fundamental Definitions - Local Field -
Claussius-Mossotti Relation -Different Types of Electric Polarizations (electronic and ionic
polarizations) - Frequency and Temperature Effects on Polarization - Dielectric Loss.
MAGNETIC PROPERTIES: Introduction - Fundamental Definitions - Different Types of
Magnetic Materials - Weiss Theory of Ferromagnetism - Domain Theory of Ferromagnetism -
Hysteresis - Hard and Soft Magnetic Materials.
UNIT – III ULTRASONICS: Introduction - Production of Ultrasonics by Magnetostriction and Piezo-
electric Effects - Detection and Applications of Ultrasonics.
INTERFERENCE: Introduction - Interference in Thin Films - Wedge Shaped Film - Newton‟s
Rings - Lloyd‟s mirror - Michelson‟s Interferometer and Applications.
UNIT-IV
DIFFRACTION: Introduction - Differences between Fresnel and Fraunhofer Diffractions -
Single Slit Diffraction (Qualitative and Quantitative Treatment) - Differences between
Interference and Diffraction - Gratings and Spectra-Multiple Slits -Diffraction Grating -X-ray
Diffraction - Bragg‟s Law.
POLARISATION: Introduction - Double Refraction - Negative Crystals and Positive Crystals -
Nicol‟s Prism - Quarter Wave Plate and Half Wave Plate - Production and Detection of
Circularly and Elliptically Polarised
UNIT-V
LASERS: Introduction - Spontaneous and Stimulated Emissions - Population Inversion – Ruby
Laser - He-Ne Laser - Semiconductor Laser - Applications.
19
FIBRE OPTICS: Introduction - Optical Paths in Fibre - Optical Fibre and Total Internal
Reflection - Acceptance Angle and Cone of a Fibre - Fibre Optics in Communications -
Applications.
Prescribed Books :
Physics Part I & II Resnick, Halliday, Krane. John Wiley & Sons
Solid State Physics P.K. Palanisamy. Scitech Publications (India) Pvt. Ltd,
Chennai.
Engineering Physics P.K. Palanisamy. Scitech Publications (India) Pvt. Ltd,
Chennai.
A Text Book of Engg. Physics Kshirsagar & Avadhanulu. S.Chand and Co.
Reference Books:
Engineering Physics R.K.Gaur and S.L.Gupta. Dhanpat Rai & Sons, Delhi.
Solid State Physics S. O. Pillai.New Age International(P)Limited,New Delhi.
Materials Science M.ArumugamAnuradhaAgencies,Kumbhakonam.
The Feynman Lectures on Physics Addison-Wesley.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EIRCH 104: ENVIRONMENTAL STUDIES
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
The objective of the syllabus is to provide knowledge in the basic concepts of the Environmental
Studies in Engineering subjects.
Unit – I
Multidisciplinary nature of environmental studies & Natural Resources:
Multidisciplinary nature of environmental studies: Definition, scope and importance,
need for public awareness. Natural Resources: Renewable and non-renewable resources, natural
resources and associated problems. Forest resources: Use and over-exploitation, deforestation,
case studies. Timber extraction, mining, dams and their effects on forest and tribal people. Water
resources: Use and over – utilization of surface and ground water, floods, drought, conflicts over
water, dams- benefits and problems. Mineral resources: Use and exploitation, environmental
effects of extracting and using mineral resources, case studies. Food resources: World food
20
problems, changes caused by agriculture and overgrazing, effects of modern agriculture,
fertilizer-pesticide problems, water logging, salinity, case studies. Energy resources: Growing
energy needs, renewable and non renewable energy sources, use of alternate energy sources,
Case studies. Land resources: Land as a resource, land degradation, man induced landslides, soil
erosion and desertification. Role of an individual in conservation of natural resources. Equitable
use of resources for sustainable lifestyles.
Unit - II
Ecosystems and Biodiversity and its conservation:
Concept of an ecosystem. Structure and function of an ecosystem. Producers, consumers
and decomposers. Energy flow in the ecosystem. Ecological succession. Food chains, food webs
and ecological pyramids. Introduction, types, characteristic features, structure and function of
the following ecosystem:- Forest ecosystem. Grassland ecosystem. Desert ecosystem. Aquatic
ecosystems (ponds, streams, lakes, rivers, oceans, estuaries). Biodiversity and its conservation
Introduction – Definition: genetic, species and ecosystem diversity. Biogeographical
classification of India. Value of biodiversity: consumptive use, productive use, social, ethical,
aesthetic and optional values. Biodiversity at global, National and local levels. India as a mega –
diversity nation. Hot-spots of biodiversity. Threats to biodiversity: habitat loss, poaching of
wildlife, man-wildlife conflicts. Endangered and endemic species of India. Conservation of
biodiversity: In – situ and Ex-situ conservation of biodiversity.
Unit – III
Environmental Pollution
Environmental Pollution: Definition, causes, effects and control measures of :- Air
Pollution, Water pollution, Soil pollution, Marine pollution, Noise pollution, Thermal pollution,
Nuclear hazards, Solid waste Management: Causes, Effects and control measures of urban and
industrial wastes. Role of an individual in prevention of pollution. Pollution case studies. Diaster
Management: floods, earthquake, cyclone and landslides.
Unit – IV
Social Issues and the Environment:
From Unsustainable to Sustainable development. Urban problems related to energy.
Water conservation, rain water harvesting, watershed management. Resettlement and
rehabilitation of people: its problems and concerns. Case Studies, Environmental ethics: Issues
and possible solutions. Climate change, global warming, acid rain, ozone layer depletion, nuclear
accidents and holocaust. Case Studies. Wasteland reclamation. Consumerism and waste
products.
Unit - V
Human Populations and the Environment and Environment Production Act and Field
Work:
Population growth, variation among nations. Population explosion – Family Welfare programme.
Environment and human health. Human rights. Value Education. HIV/AIDS. Women and Child
Welfare. Role of Information Technology in Environment and human health. Case Studies.
Environment Protection Act. Air (Prevention and Control of Pollution) Act. Water (Prevention
21
and Control of Pollution) Act. Wildlife Protection Act. Forest Conservation Act. Issues
involved in enforcement of environmental legislation. Public awareness. Field Work: Visit to
local area to document environmental assets river / forest / grassland / hill / mountain. Visit to
local polluted site – Urban / Rural / Industrial / Agricultural. Study of common plants, insects,
birds. Study of simple ecosystems-pond, river, hill slopes, etc.
Text Book:
1. Text book of environmental studies for undergraduates courses by Each Bharuchs,
published by – University Grants Commission, Universities Press, India.
2. Text book of environmental studies for undergraduates courses by Benny Joseph.
published by Tata Mc Graw Hill Publishing company limited.
3. Text book of environmental studies by Kaushik & Kaushik.
References:
1. Agarwal, K.C. 2001 Environmental Biology, Nidi Publishing Ltd., Bikaner.
2. Brunner R.C., 1989, Hazardous Waste Incineration, Mc Graw Hill Inc.480p.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EIRCS 105: PROGRAMMING with C
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
The Aim of the course is to acquaint the student with C and the applications of C.
UNIT – I
Variables, Expressions and Basic Input-Output:
Introduction to C, Historical Development of C, Features of C, Compilers, Linker, Preprocessor,
Character Set, Constants, Variables, Data Types and Keywords, Typedef statement, Operators,
Operator – Precedence and Associativity, Typecasting.
Basic Input-Output: Introduction, Single Character Input-Output, String Input-Output, Types of
Character in format String, Search sets.
UNIT – II
Control Structures: Introduction, the if statement, if-else statement, Multiway decision,
Compound statements, Loops-for Loop, While Loop, do-while Loop, Break statement, Switch
statement, Continue statement, Goto statement, simple examples algorithms and flowcharts.
UNIT – III
22
Functions: Introduction, Function main, where are functions useful, Functions accepting more
than one parameter, User Defined and Library functions, Concepts Associated with Functions,
Function Parameters, Call by Value and Call by Reference, Return Values, Recursion,
Comparison of Iteration and Recursion, Variable Length Argument Lists.
Storage classes: Automatic, Register, Static and external storage classes.
UNIT – IV
Arrays And Strings: Introduction to Arrays, Initialization of Array, How arrays are useful,
Multi dimensional Arrays.
Strings: What are Strings, Arrays of Strings and Standard Library String Functions.
Pointers: Introduction, Definition and use of pointers, Address operator, Pointer variables,
Dereferencing Pointers, Void Pointers, Pointer Arithmetic, Pointers to Pointers, Pointers and
Arrays, Passing arrays to Functions, Pointers and Functions.
UNIT – V
Structures, Unions And Files:
Introduction, Declaring and Using Structures, Structure initialization, Structure within a
Structure, Operations on Structures, Array of Structures, Array within Structure, Pointers to
Structures, Pointers Within Structures, Structures and Functions,
Unions:, Differences between Unions and Structures, Operations on Unions, Scope of a Unions,
Bit fields.
Files: Introduction, File Structure, File handling functions, File Types, Unbuffered and Buffered
Files, Error Handling.
Text Books:
MASTERING C, by K R Venugopal, S R Prasad published by Tata McGraw Hill.
Reference Books:
Programming with ANSI and Turbo C by Ashok N. Kamthane, PEARSON Education
Let us C by Yashwant Kanetkar, published by BPB Publications.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EFRME106: GEOMETRICAL DRAWING
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
23
Unit I
Orthographic projections and Projection of points
Introduction to orthographic projections: First angle projection and third angle projection.
Projection of points
Projection of straight lines
Projection of straight lines: line parallel to one or both planes, line perpendicular to one of the
planes, line inclined to one plane, line inclined to both the planes. True length of straight line and
true angles and its traces.
Unit II
Projections of planes
Introduction, types of planes, perpendicular planes, perpendicular to one pane and parallel to
other plane, perpendicular to one plane and inclined to other plane, oblique planes.
Projections on auxiliary planes: types of auxiliary planes, perpendicular to one pane and parallel
to other plane, perpendicular to one plane and inclined to other plane, oblique planes.
Unit III
Projections of solids
Introduction, types of solids, polyhedral tetrahedron- prism, pyramid and solids of revolution-
cylinder, cone. Projections of solids, simple positions, axis inclined to one plane and parallel to
other, axis inclined to both the planes.
Unit IV
Developments of surfaces
Developments of lateral surfaces of right solids- cube, prisms, cylinders, pyramids and cones.
Sections of solids:
Introduction, section planes, sections and true shape of a section. Sections and sectional views of
solids- prism, pyramid, cylinder and cone.
Unit V
Isometric projections:
Introduction, isometric axes, lines and planes. Isometric scale, isometric view and projections of
solids in simple position- prism, pyramid, cylinder, cone and sphere.
Text books:
1. “Engineering Drawing” by N.D. Bhatt and V. M .Panchal, Charotar publishing house Pvt.
Ltd, 49th edition, 2008.
2. “Engineering Drawing” by M.B Shah and B.C Rana, Pearson Edn, 2nd
edition, 2009
Five Year Dual degree (B. Tech + M.Tech)
24
Mechanical Engineering- First Semester
EIRCS111: C-PROGRAMMING LAB
Hours per week: 3
Credits: 2 Sessionals: 100 Marks
1. Write a program to read the coordinates of a triangle and find the area. Check whether
the given points form a triangle or a straight line.
2. Write a program to find the roots of a quadratic equation.
3. Write a program to check whether the given number is prime or not.
4. Write a program to print the Pascal triangle.
5. Write a program to print Fibonacci series up to a given number.
6. Write a function to find the value of nCr.
7. Write a program to implement binary search.
8. Write a function to swap to numbers by using call by reference.
9. Write a program to delete redundant elements in a given set of values.
10. Write a program to find maximum element of a given array
11. Write a program to arrange the elements in a ascending order.
12. Write a program for addition, multiplication of two given matrices of order M x N.
13. Write a program to check whether the given square matrix is symmetric or not.
14. Write a program to count the no. of words and no. of each vowel in a given sentence.
15. Write a function to sort the given list of names in dictionary order. (use string
handling functions)
16. Write a program to read N student records having fields (sno, sname, sex, cgpa) and
sort them by CGPA.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EIRPH112 ENGINEERING PHYSICS LAB
Hours per week: 3
Credits: 2 Sessionals: 100 Marks
The main aim of the course is to acquaint the students with basic concepts in Engineering
Physics using the following illustrative list of experiments.
1. J – by Callender and Barne‟s Method.
2. Thermal Conductivity of a Bad Conductor – Lee‟s Method.
3. Magnetic Field Along the Axis of a Circular Coil Carrying Current – Stewart and Gee‟s
Galvanometer.
4. Hall Effect- Measurement of Hall Coefficient.
5. Carey Foster‟s Bridge – Laws of Resistance and Specific Resistance.
6. Calibration of Low Range Voltmeter – Potentiometer Bridge Circuit.
7. Thickness of a Paper Strip- Wedge Method.
8. Newton‟s Rings – Radius of Curvature of a Plano Convex Lens.
9. Diffraction Grating – Normal Incidence.
25
10. Determination of Refractive Indices (o and e) of a Bi-Refringent Material (Prism).
11. Cauchy‟s Constants – Using a Spectrometer.
12. Dispersive Power of a Prism – Using a Spectrometer.
13. Determination of Rydberg Constant.
14. LASER – Diffraction.
15. Determination of Band Gap in a Semiconductor.
16. Optical Fibres – Numerical Aperture and Loss of Signal.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- First Semester
EIRME113: WORKSHOP TECHNOLOGY LAB
Hours per week: 3
Credits: 2 Sessionals: 100 Marks
The main aim of Workshop Technology is to acquaint the student with the basic tools used in
Workshop Technology and to develop skills in using these tools to perform simple tasks. The
students should be able to work with these tools to prepare simple jobs in Wood Work
Technology, Sheet Metal Working, Forging Technology and Fitting Technology .
An illustrative list of tasks to be performed by the student is given below:
I. Wood Working Technology - Familiarity with different types of woods used and tools used
in wood Working technology.
Tasks to be performed:
1) To make Half – Lap joint 2) To make Mortise and Tenon joint
3) To make Corner Dovetail joint 4) To make Briddle joint.
II. Sheet Metal Working – Familiarity with different types of tools used in sheet metal working,
developments of sheet metal jobs from GI sheets, knowledge of basic concepts of soldering.
Tasks to be performed:
1) To make Square Tray 2) To make Taper side Tray
3) To make Conical Funnel 4) To make Elbow Pipe.
III. Forging Technology – Familiarity with different types of tools used in forging technology.
Knowledge of different types of furnaces like coal fired, electrical furnaces etc...
Tasks to be performed:
1) To make round M.S rod to square
rod
2) To make L bend in given M.S. Rod.
26
3) To make S bend in given M.S. Rod. 4) To perform heat treatment tests like
annealing,normalizing etc..
IV. Fitting Technology – Familiarity with different types of tools used in fitting technology.
Tasks to be performed:
1) To make “V” – fitting 2) To make Rectangular fitting
3) To make Dovetail fitting 4) To make Semi circular fitting
5) To make Hexagon fitting
Student is required to work individually and complete at least three jobs in each
technology.
Dress Code:
For Boys : Blue Colour Long Apron, Khaki Trousers, Half Sleeve Shirt (Tucked-in ), Black
Leather Shoes.
For Girls : Blue Colour Long Apron, Salwar Suit, Black Shoes.
Reference Book:
Workshop Technology, Part 1, W.A.J. Chapman, Viva Low Priced Student Edition.
Elements of Workshop Technology, Volume 1, S.K.Hajra Choudhury, S.K.Bose.
A.K.Hajra Choudhury and Nirjhar Roy, Media Promoters and Publishers Pvt. Ltd.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRMT 201: Engineering Mathematics - II
Hours per week: 4 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
The objective of the course is to impart knowledge in Basic concepts of Mathematics relevant to
Engineering applications.
Unit – I
Partial Differentiation:
Introduction to Partial differentiation, Total derivative, Differentiation of implicit functions,
Geometrical interpretation, Tangent plane and normal to a surface, Change of variables,
Jacobians, Taylor‟s theorem for functions of two variables.
Unit –II
Applications Of Partial Differentiation:
27
Total differential, Maxima and minima of functions of two variables, Lagrange‟s method of
undetermined multipliers, Differentiation under the integral sign, Leibnitz‟s Rule.
Unit-III
Partial Differential Equations:
Introduction, Formation of partial differential equations, Solutions of a partial differential
equation, Equations solvable by direct integration, Linear equations of the first order, Non-linear
equations of the first order, Homogeneous linear equations with constant coefficients, Rules for
finding the complementary function, Rules for finding the particular integral.
Unit-IV
Linear Algebra-1:
Rank of Matrix, Elementary transformations, Elementary matrices, Inverse, Normal form,
Consistency of linear system of equations, Linear transformations.
Unit-V
Linear Algebra – 2:
Eigen value and eigen vectors of a matrix, Cayley-Hamilton theorem, Reduction to diagonal
form, Quadratic forms and canonical forms, Hermitian and Skew Hermitian matrix, Unitary
matrix.
Text Books Prescribed :
Higher Engineering Mathematics, Dr.B.S Grewal. Khanna Publishers.
References :
Advanced Engineering Mathematics, Erwin Kreyszig. Wiley Eastern Pvt. Ltd.
Textbook of Engineering Mathematics, N.P.Bali. Laxmi Publications (P) Ltd.
Higher Engineering Mathematics, Dr.M.K.Venkata Raman. National Pub. Co.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRMT 201: Engineering Mathematics - III
Hours per week: 4 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
The objective of the course is to impart knowledge in Basic concepts of Mathematics relevant to
Engineering applications.
Unit-I
Fourier Series:
Euler‟s formulae, Conditions for a Fourier expansion, Functions having points of discontinuity,
Change of interval, Odd and even functions, Expansions of odd or even periodic functions, Half
range series and practical Harmonic Analysis.
Unit-II
Laplace Transforms:
Transforms of elementary functions, Properties of Laplace transforms, Existence conditions,
28
Inverse transforms, Transforms of derivatives, Transforms of integrals, Multiplication by tn,
Division by t, Convolution theorem.
Unit-III
Applications Of Laplace Transforms:
Applications to ordinary differential equations and simultaneous linear equations with constant
coefficients, Unit step function, Unit impulse function, Periodic functions (without proofs).
Unit-IV
Vector Calculus (Differentiation-):
Scalar and vector fields, Gradient, Divergence, Curl, Directional derivative, Identities,
Irrotational and Solenoidal fields.
Unit-V
Vector Calculus (Integration) :
Line integral, Surface integral, Volume integral, Green‟s theorem in the plane, Stoke‟s and
Gauss divergence theorems with proofs, Introduction of orthogonal curvilinear co-ordinates,
Cylindrical co-ordinates, Spherical polar co-ordinates (without proof)
Text Prescribed :
Higher Engineering Mathematics, Dr.B.S Grewal. Khanna Publishers.
References :
Advanced Engineering Mathematics, Erwin Kreyszig. Wiley Eastern Pvt. Ltd.
Textbook of Engineering Mathematics, N.P.Bali. Laxmi Publications (P) Ltd.
Higher Engineering Mathematics, Dr.M.K.Venkata Raman. National Pub. Co.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRCH 203 Engineering Chemistry
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
Unit-I:
ELECTROCHEMISTRY & CORROSION AND ITS CONTROL:
Electrode Potential –Determination of Single Electrode Potential-Reference Electrodes –
Hydrogen and Calomel Electrodes. Electrochemical Series and its Applications. Primary Cell–
Dry or Leclanche Cell, Secondary Cell – Lead acid storage Cell –
Definition of Corrosion, Theories of Corrosion –Dry Corrosion and Electro Chemical Corrosion
Factors Affecting Corrosion- Nature of the Metal and Nature of the Environment. Prevention of
Corrosion: Metallic Coatings –Galvanising and Tinning, Anodized Coatings, Cathodic
Protection- Inhibitors, Organic Coatings-Paints –Characteristics, Constituents and their
functions, Varnishes.
UNIT-II.
29
FUEL TECHNOLOGY: CALORIFIC VALUE AND SOLID FUELS:
Classifications of Fuels – Characteristics of Fuels- Calorific Value - Units. Determination –
BombCalorimetric Method- Dulong‟s formula. Solid Fuels–Coal, Classification of Coal by
Rank-Analysis of Coal –Proximate and Ultimate Analysis. Coke: Manufacture of Coke-
Beehive oven and Otto Hoffmann‟s by product Oven processes.
UNIT-III.
FUEL TECHNOLOGY: LIQUID FUELS:
Refining of Petroleum - Petroleum products used as Fuels - Gasoline - Knocking and Octane
Number of Gasoline, Synthetic Petrol –Bergius and Fishcher Tropsch methods. Diesel - Cetane
Number, High speed and low speed Diesel oil.- Power Alcohol: Manufacture, Advantages and
Disadvantages - LPG.
Unit-IV:
ENGINERING MATERIAL SCIENCE:
Introduction to nano materials- structure sensitive materials-Elementary ideas about electrical,
thermal and magnetic properties of materials
Refractories:– Classification - criteria of a good refractory. Preparation and properties of silica,
magnesite and silicon carbide refractories - clay bond, silica nitride bond and self bond in silicon
carbide.
Lubricants:
Classification-Properties- Viscosity and Oiliness, Flash and Fire - Points, Cloud and Pour -
Points. Aniline point, Saponification number – Carbon residue, Emulsification number
volatilities, precipitation number, specific gravity, neutralization number. Principles and
Mechanism of Lubrication - Fluid Film, Boundary and Extreme - Pressure Lubrications
Unit-V:
HIGHPOLYMERS & COMPOSITE MATERIALS: 8hours Types of
Polymerization– Mechanism of addition polymerization-Moulding constituents. Differences
between Thermo Plastic and Thermosetting Resins. Preparation and Properties of Polyethylene,
PVC, Polystyrene, Polyamides (Nylon-6:6), Polycarbonates and Bakelite - Engineering
applications of Plastics.
Composite materials: Introduction –constituents of composites-types of composites-Processing
of fibre reinforced composites.
Text Books Prescribed :
Engineering Chemistry,P.C. Jain and M. Jain. Dhanapat Rai & Sons, Delhi.
Engineering Chemistry, B.K.Sharma. Krishna Prakashan, Meerut.
A Textbook of Engineering Chemistry, Sashi Chawla. Dhanapath Rai & Sons, Delhi.
Chemistry of Engg materials by Jain &Jain Dhanapath Rai & Sons, Delhi.
Physical chemistry by Laidler
30
Reference Books :
A Textbook of Engineering Chemistry, S.S.Dara. S.Chand & Co. New Delhi.
Material Science and Engineering, V.Raghavan. Prentice-Hall India Ltd.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRPH 204 MATERIALS SCIENCE
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
CRYSTAL GEOMETRY AND STRUCTURE DETERMINATION: Space Lattices and Unit
Cells - Crystal Systems - Miller Indices - Representation of Directions and Planes - Structure
Determination using X‐ray Diffraction - Bragg's Law and Lattice Parameter Determination -
Bonding in Solids - Coordination Number.
CRYSTAL IMPERFECTIONS: Point Defects - Impurities - Dislocations: Edge and Screw
Dislocation - Stacking Faults.
UNIT II
PHASE DIAGRAMS AND PHASE TRANSFORMATIONS: Definition of Diffusivity -
Concept of Activation Energy - Fick‟s Laws of Diffusion Mechanism and their Applications -
Diffusion Process - Phase - Phase rule - Unary, Binary Phase Diagrams - Phase Diagrams of
some Important Metals - Solidification and Crystallization - Glass Transition.
UNIT III
MECHANICAL BEHAVIOUR: Elastic Behaviour of Materials - Atomic Model of Elastic
Behaviour - Rubber-Like Elasticity - Inelastic Behaviour - Plastic Deformation - Tensile Stress -
Strain Curve - Pastic Deformation by Slip - The Shear Strength of Perfect and Real Crystals -
Creep - Mechanism of Creep - Creep Resistant Materials - Fracture - Ductile Fracture - Brittle
Fracture - Fracture Toughness - Ductile-Brittle Transition.
UNIT IV
MODERN PHYSICS (QUANTUM PHYSICS): Matter Waves - Heisenberg‟s Uncertainty
Principle - Schrodinger‟s Time Independent Wave Equation - Physical Significance of Wave
Function ( ) - Application to a Particle in a one Dimensional Box (Infinite Potential Well) -
Free Electron Theory of Metals - Band Theory of Solids (qualitative) - Distinction between
Metals, Insulators and Semiconductors - Elementary Concepts of Maxwell Boltzmann, Bose
Einstein and Fermi Dirac Statistics (No Derivation).
31
UNIT V
NANOSCIENCE : Definition of Nanoscience and Nanotechnology - Energy Bands - Band
Structure in Nano - Surface Energy (Qualitative) - Size Dependent Properties (Qualitative):
Mechanical and Electrical - Growth Techniques: Top Down (Lithography) -Bottom Up (Sol-Gel
and Co-Precipitation) -Characterization Techniques: SEM and TEM - Applications -
Optoelectronics - Micro- and Nanomechanics
Prescribed Books :
Materials Science and Engineering: A First Course V. Raghavan PHI
Introduction to Nanotechnology Charles P. Poole, Frank J. Owens Wiley
Reference Books:
Solid State Physics S.O.Pillai. New Age International (P) Limited, New Delhi.
Materials Science M. Arumugam. Anuradha Agencies, Kumbhakonam.
Nanotechnology- Technology Revolution of 21st Century Rakesh Rathi. S.Chand & Company
Ltd, New Delhi.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRME 205 ENGINEERING MECHANICS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT – I
Basic Concepts& Equilibrium: Introduction to Engineering Mechanics – Resolution of a Force,
Moment of a Force and its applications, Varignon‟s theorem. Couples, Resultant of Force
Systems. Free Body Diagram, equilibrium of coplanar force systems.
UNIT – II
Friction: Nature of Friction, Laws of Dry Friction, Coefficient of Friction, Angle of Friction,
Static Friction, Dynamic Friction and Rolling Friction, Equilibrium of coplanar force systems
involving Frictional Forces.Trusses:Analysis of Trusses by Method of Joints and Method of
Sections.
UNIT- III
Properties of Surfaces and Solids: First moment of area and the Centroid of sections,Centroid
of Composite Areas, Centroid of an Area Bounded by two Curves, Centre of Gravity of a
32
Body, Centre of Gravity of Composite Bodies – Moment of Inertia and Product of Inertia of
Plane Areas by Integration,– Parallel axis theorem and perpendicular axis theorem – Polar
moment of inertia – Principal moments of inertia of plane areas – Principal axes of inertia - Mass
moment of inertia – Derivation of mass moment of inertia for Masses like Disc, Cylinder,
Sphere and Thin Rod.
UNIT - IV
Kinematics: Introduction to Translation, Rotation and Plane Motion of a Rigid Body.
Rectilinear Motion of a Particle with Constant Acceleration and Variable Acceleration,
Curvilinear Motion of a Particle using Rectangular Coordinates, and Normal and Tangential
Coordinates, Angular Motion of Rigid Body with Constant Angular Acceleration and Variable
Angular Acceleration, Plane Motion of Rigid Body. Instantaneous centre for Plane Motion
Kinetics:Force, Mass and Acceleration: Introduction, Newton‟s Laws of Motion, Equations of
Motion of a Particle in Rectilinear and Curvilinear Motion, Motion of Mass centre of a System
of Particles, Equations of Motion of a Rigid Body in Rotation and Plane Motion, D‟ Alembert‟s
Principle.
UNIT – V
Kinetics:Work and Energy –Impulse and Momentum: Work Done by a Force and a System
of Forces, Work done by a Varying force, Energy, Potential Energy, Kinetic Energy of a Particle,
Kinetic Energy of a Rigid Body in Rotation and in Plane Motion, Work and Energy Principle,
Law of Conservation of Energy.Linear Impulse, Linear Momentum, Principle of Linear Impulse
and Linear Momentum, Conservation of Linear Momentum, Direct Central Impact, Coefficient
of Restitution.
Text Books:
1. Engineering Mechanics by S. Timoshenko and D.H.Young, McGraw-Hill
International Edition – SI Version
Reference Books:
1. Engineering Mechanics – Statics and Dynamics by Ferdinand L. Singer, Harper
International Edition
2. Engineering Mechanics – Statics and Dynamics by Irving Shames, Prentice Hall of India
3. Engineering Mechanics – Volume I Statics by J. L. Meriam and L. G. Kraige, John
Wiley and Sons
4. Engineering Mechanics – Statics and Dynamics by McLean and Nelson( Schaum‟s
Outline Series), McGraw-Hill Book Co.
33
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRME 206: ENGINEERING ECONOMICS
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT-I:
Economics: Utility, Value, Wealth, Consumption, Wants – Necessaries, Comforts and Luxuries.
Demand: Laws of Demand, Elasticity of Demand – Price Elasticity of Demand, Factors
affecting Elasticity of Demand.
UNIT II: Forms of Business organization: Single Trader, Partnership and Public Limited Company.
Costing: Cost Concepts, Elements of Cost, Methods of Distribution of Overhead Costs. Unit
Costing, Job Costing and Process Costing.
UNIT-III:
Break-Even Analysis: Assumptions, Break – Even Charts, Simple problems.
Depreciation: Depreciation Methods.
UNIT-IV:
Accounts: Preparation of Profit and Loss account and Balance sheet (Outlines only).
Principles of Organization: Types of organization – Span of management – Authority
Delegation and Decentralization - Source of Formal Authority- Difference between Authority
and Power – Line and Staff Authority.
UNIT-V:
Principles of Management: Importance of Management – Definition of Management –
Management Process- Roles of Manager- Management, a Science or Art- Management, a
Profession – Functions of Management. Leadership – Difference between a leader and a
Manager – Characteristics of Leadership – Functions of a Leader.
Text Books:
1. Engineering Economics, Vol – 1, Tara Chand, Nem Chand & Bros, 13th ed.
2. Industrial Engineering and Management by O.P.Khanna, Khanna publishers Ltd
References:
1. Engineering and Managerial Economics by Maheswari, . Sultan chand& Co, 19th ed.
2. A Text book of Economic Theory by Dhingra and Garg, Sultan chand& sons, 2nd
ed.
3. Cost accounts by Shukla and Grewal, S.Chand& company, 14th ed.
4. Principles and Practice of Management by L.M.Prasad, Sulltan Chand & Sons
34
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRCH 211:ENGINEERING CHEMISTRY LAB
Hours per week: 3
Credits: 2 Sessionals: 100 Marks
The objective of the Laboratory Practical is to make the student to acquire the basic concepts in
Engineering Chemistry.
1. Calibration of Volumetric Apparatus.
2. Determination of sodium carbonate in soda ash.
3. Estimation of Iron as Ferrous Iron in an Ore Sample.
4. Estimation of copper (II) present in a brass sample (iodometric method)
5. a) Determination of Viscosity of a Liquid.
b) Determination of Surface Tension of a Liquid.
6. Determination of Mohr‟s Salt by potentiometric method.
7. Determination of Strength of an acid by pH metric method.
8. Conduct metric titration of mixture of weak and strong acid with sodium Hydroxide.
9. Determination of calcium hardness and magnesium hardness of water sample
10. Colorimetry
a) Estimation of Manganese
b) Estimation of Iron ( III)
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIREG 212: English Language Lab
Hours per week: 3
Credits: 2 Sessionals: 100 Marks
Topics Periods
Introduction to Phonetics 1
Accent / Stress 1
Intonation 1
Telephone Etiquette 1
Synonyms 1
Antonyms 1
One word Substitutes 1
Foreign Phrases 1
Idiomatic Expressions 2
Vocabulary & Grammar Exercises 2
35
Listening Comprehension 1
Total 13
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Second Semester
EIRME 213 ENGINEERING GRAPHICS LAB
Hours per week: 3
Credits: 2 Sessionals: 100 Marks
1. Introduction to AutoCAD, Beginning a new drawing, exploring and interacting with the
drawing window, saving and opening a file, Coordinate systems (Cartesian ,polar and
relative co-ordinate system)
2. Introduction to draw commands – line, circle, rectangle, polygon etc.
3. Introduction to modify commands – extend, trim, chamfer, rotate, etc.
4. Introduction to dimensioning and object properties.
5. Engineering Curves – Conics –general method, cycloid, epicycloids, hypocycloid,
involutes.
6. Projection of planes
7. Sections and sectional views of solids – prism, pyramid, cylinder, cone
8. Developments of solids- prism, pyramid, cylinder, cone.
9. Intersection of solids- prism to prism, cylinder to cylinder
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME301: MANUFACTURING TECHNOLOGY – I
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Foundry: Fundamentals: Introduction to Casting Process, Process Steps, Advantages,
Applications, Pattern Materials, Pattern Types and Pattern Allowances, Color Coding. Moulding
Materials, Basic Ingredients, Additives, Importance of Constituents. Moulding Tools and
Equipment – Sand Slinger, Tolling, MIC, Jolt-Squeeze.
Moulding & casting processes: Sand Moulding, Types – Green, Dry, Skin Dried, Loam Sands.
Cores, types of Cores, Core making, Core Prints. CO2 Moulding, Shell Moulding. Investment
Casting, Centrifugal Casting, die Casting–Gravity & Pressure die Casting (hot chamber, cold
chamber)
UNIT II
36
Gating & Risering: Gating System, Elements of Gating System, Sprue Design, Aspiration
Effect, Gating Ratio, Runner Design, Calculation of Gating System Dimensions for Simple
Objects. Risering System - Riser Design, Design Considerations in Casting.
Melting & Casting: Melting Furnaces – Crucible Furnace, Cupola, Charge Calculations, arc
Furnace, Solidification of Casting, Casting Defects, Remedies.
UNIT III
Joining :Fundamentals: Classification of Welding Processes, Types of Welds, Types of Joints,
Welding Positions, Edge Preparation, Welding Related Terminology.
Arc Welding: Equipment, Electrodes, Electrode Coatings, Principle of Arc, Mode of Metal
Transfer, V-I Characteristics of Power Source, Shielded Metal are Welding, Submerged are
Welding, Plasma arc Welding, Tungsten Inert Gas Welding (TIG), Metal Inert Gas (MIG)
welding.
Gas Welding: Equipment, Oxy – Acetylene Flame, Types, Gas Welding Procedure, Oxygen –
Hydrogen Welding, Gas Cutting.
UNIT IV
Resistance Welding: Principle, Spot Welding, Seam Welding, Projection Welding, Flash Butt
Welding.
Other Welding Process: Friction Welding, Laser Beam Welding, Thermit Welding.
Brazing, Braze Welding, Soldering, Adhesive Bonding, Weld Defects.
Forming: Fundamentals, Introduction to Metal Working Process, Hot Working, Cold Working.
Rolling: Rolling Fundamentals, Analysis of Rolling Process, Rolling Stand Arrangements,
Rolling Passes.
UNIT V
Extrusion Drawing: Extrusion Fundamentals, Classification of Extrusion, Wire Drawing, Tube
Drawing, Impact Extrusion, Hydrostatic Extrusion.
Forging: Fundamentals, Forging, Die Forging, Roll Forging, Press Forging, Upset Forging
Sheet Metal working: Principles of Sheet Metal Working – Spring Back & Shearing. Types of
Dies, Drawing, Bending, Punching, Blanking, Spinning, Coining, Embossing.
Text Books:
1. Manufacturing Technology, P.N.Rao, Tata Mc. Graw Hill, Second edition 2004.
References:
1. Principles of Casting, Rossenthol, Tata Mc.Graw hill, New Delhi.
2. Welding & welding Technology, Tata Mc Graw hill, Richard L Little, Nineteenth Report,
1999.
3. Tool Design, Cyrll Donalson, George H.Lecon, V.C. Goold, Third edition, Tata Mc Graw
hill 2000.
37
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME302 MECHANICS OF SOLIDS-I
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Simple Stresses and Strains: Classification of Loads, Stress, Strain, Stress and Elongation
Produced in a Bar due to its self weight, Tie Bar of uniform strength, Elongation in case of a
Taper Rod, Poisson‟s Ratio, Relation Between the Elastic Modulii, Stresses Induced in
Compound Bars , Thermal Stress and Strain.
UNIT II
Shear Force and Bending Moment : Basic Definitions, Classification of Beams, Types of
Loads, Types of Supports, S.F. and B.M. Diagrams for Cantilever, Simply Supported and
Overhanging Beams for different types of Loadings, The Point of Contraflexure, General
Relation between the Load, the Shearing Force and the Bending Moment-Problems.
UNIT III
Bending and Shear Stresses in Beams: Theory of Simple Bending (Bending equation/ Flexural
Formula), Position of Neutral Axis, Section Modulus, Practical Application of Bending
Equation, Shear Stresses in Beams, Variation of Shear Stress Distribution for Rectangular,
Circular and I-Sections-Problems.
UNIT IV
Complex and Principal Stresses: Introduction, Stresses on an oblique plane under Uniaxial
loading, Stresses on an oblique plane under Biaxial Loading, Complementary Shear Stress,
Simple Shear, Pure Shear, Biaxial stresses combined with Shear stresses, Principal stresses and
principal planes, Mohr‟s circle for Complex stresses.
Torsion of Circular Shafts: Shafts, Torsion of Shafts, Torsion equation, Hollow Circular
Shafts, Torsional Rigidity, Power Transmitted by the Shaft, Importance of Angle of Twist and
Shear Stresses in Shafts, Shafts in Series, Shafts in Parallel, comparison of Solid and Hollow
Shafts, Combined Bending and Torsion.
UNIT V
Deflection of Beams: Beam Deflection, Relation between Slope, Deflection and Radius of
Curvature, Slope and Deflection at a Section, Double Integration Method, Macaulay‟s Method
and Moment Area Method for Cantilever, Simply Supported, overhanging, propped cantilever
Beams
38
Text Book:
1. Strength of Materials by Dr.Sadhu Singh, Khanna Publishers, New Delhi.
References:
1. Strength of Materials by Timoshenko, Part-I & II , 3rd
edition, CBS Publishers &
Distributors, New Delhi.
2. Mechanics of Solids by Popov, 2nd
Edition, Pearson Education, 2003, New Delhi.
3. Mechanics of Materials by F.P.Beer, E.R. Johnston, Jr & John.T.. Dewolf, 3rd
edition, Tata
McGraw-Hill Publishing Company Limited, New Delhi.
4. Strength of Materials by Dr.R.K.Rajput, First multi colour Revised Edition 2006, S.Chand &
Company Limited, New Delhi.
5. Mechanics of solids by Crandal, Dahl and Lardner.
39
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME303: APPLIED THERMODYNAMICS – I
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Introduction- Basic Concepts: Introduction- Basic Concepts - Thermodynamic Systems,
Perfect Gas laws- Equation of State- Universal Gas Constant Vander Waal‟s Equation of State.
Thermodynamic Systems, Micro & Macro Systems- Homogeneous and Heterogeneous Systems
- Concept of Continuum- Pure Substance - Thermodynamic Equilibrium, State Property, Path,
Process- Reversible and Irreversible Cycles. Specific Heats at Constant Volume and Pressure.
Energy as a Property of the Systems- Energy in state and Transition, Work, Heat, Point
Function, Path Function.
First law of Thermodynamics: Joule's Experiments- First law of Thermodynamics-
Corollaries- First law of Thermodynamics Applied to Various Non-Flow Processes- Properties
of end States- Heat Transfer and Work Transfer- Change in Internal Energy. Systems
Undergoing a Cycle and Change of State - Throttling and free Expansion-. First law Applied to
Flow Systems- Steady Flow Energy Equation - First law Applied to Steady Flow Processes. First
law Applied to Isolated Systems - Limitations of First law of Thermodynamics. Application of
First law of Thermodynamics for Flow and Non-Flow Processes.
UNITII
Second law of Thermodynamics: Kelvin Plank Statement and Clausius Statement and their
Equivalence, Corollaries- Perpetual Motion Machines of first kind and second kind-
Reversibility and Irreversibility- Cause of Irreversibility- Carnot Cycle- Heat Engines and
Heat Pumps- Carnot Efficiency- Clausius Theorem- Clausius Inequality- Concept of Entropy-
Principles of Increase of Entropy..
Availability and irreversibility: Definitions and Expression for Availability and Irreversibility,
Energy and Available Energy. Helmholtz Function and Gibbs Function- -Availability in Steady
Flow- and Non-Flow Processes. Entropy Equation for Flow Process- Irreversibility and Change
of Entropy.
UNIT III
Properties of Steam and use of Steam Tables: Measurement of Dryness Fraction- T-S and H-S
Diagrams. Problems Related Various Thermodynamic Processes under gone by Steam.
Vapor Power Cycles: Vapor Power Cycle-Rankine Cycle- Thermodynamic Variables Effecting
Efficiency and output of Rankine Cycle-. Problems related to Rankine Cycle-, Theory Related to
Re-heat cycle- Regenerative Cycle
UNITIV
I.C. engines: Classification, Comparison of two Stroke and Four Stroke Engines, Comparison of
SI and CI Engines. Air Cycles- Otto, Diesel, Dual, their Efficiencies and Analysis- Valve
Timing and Port Timing Diagrams.
40
UNIT V
Reciprocating and Rotary Compressors: Classification of Reciprocating Compressors, Effect
of Clearance- Volumetric Efficiency, Single Stage and Multi Stage Compressors, Effect of Inter-
Cooling and Pressure Drop in Multi - Stage Compressors. – Analysis of Reciprocating
Compressors. Theory of Roots blower, Vane type Blower, Centrifugal Compressor - Axial
Flow Compressors.
Text Books:
1. Engineering Thermodynamics, by P.K.Nag, Tata McGraw-Hill Publications company.
2. Thermal Engineering, by M.L.Mathur and F.S.Mehta, Jain Brothers.
References:
1. Thermal Engineering by P.L.Ballaney Khanna Publishers.
2. Thermodynamics, by Spolding and Cole.
3. Thermal Engineering by R.K. Rajput, S.Chand & Co.
4. Introduction to thermodynamics – J.B.Jones and G.A.Hawkins-John wiley &sons
5. Thermodynamics-Van wylen and Sunntagg
41
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME 304: METALLURGY Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Constitution of Alloys: Necessity of alloying, types of solid solutions, Hume-Rothery rules,
intermediate alloy phases and electron compounds.
Binary phase diagrams: Gibbs Phase Rule. Classification of binary phase diagrams. Principles
of construction and interpretation of binary phase diagrams. Lever rule. Invariant reactions. Uses
and limitations of phase diagrams. Iron-Iron carbide phase diagram.
UNIT II
Heat Treatment of Steels: Annealing, Normalizing, Isothermal Transformations Curves,
Hardening, Tempering, Austempering and Martempering of steels.
Surface hardening of Steels: Carburizing, Nitriding, Cyaniding, Flame and Induction
Hardening methods.
UNIT III
Common Ferrous alloys: Use and limitations of plain carbon steels, Wrought Iron. AISI & BIS
classification of steels. Structure, properties and applications of alloy steels- Hadfield steels,
stainless steels and tool steels. Cast Irons.
UNIT IV
Common Non-Ferrous alloys: Copper and its alloys, Aluminium and its alloys, Nickel its
alloys, Titanium and its alloys. Metals for high temperature and low temperature applications.
UNIT V
Composite Materials: Classification, Types of Matrices and Reinforcements. Fabrication
Methods. Examples and Applications.
Nano Materials: Definition, Properties and Applications.
Text Books:
1. Introduction to Physical Metallurgy by S.H.Avner, Tata McGraw-Hill Second edition 1997.
2. Composite Materials Science and Engineering by Kishan K. Chawla, Springer, 2nd
ed., 1998.
3. Nanotechnology: A Gentle Introduction To The Next Big Idea By Ratner, Pearson Education
India, 2003.
References:
1. Physical Metallurgy: Principles and Practice by V.Raghavan, Prentice Hall of India, Second
edition, 2009.
2. Material Science and Engineering – An Introduction by William D. Callister, Jr., John Wiley
and Sons Inc., Fifth Edition, 2000.
3. Engineering Metallurgy: Applied Physical Metallurgy by R.A.Higgins, Standard Publisher
Distributors Sixth Edition, 2004
4. Engineering Physical Metallurgy by Y.Lakhtin, University Press of the Pacific, 2000.
5. Physical Metallurgy by Prof. Vijendra Singh, Standard Publisher Distributors, 2005.
42
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME305: FLUID MECHANICS
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Properties of fluids- Viscosity- Pressure Measurement and Manometers- Basic Principles of
Hydrostatic Forces on Surfaces, Buoyancy, Meta centre. Fluid Kinematics & Fluid Dynamics:
Stream line- Stream Tube- Stream Function- Potential Function- Classification of Flows- -
Conservation of Mass- Equation of Continuity, Conservation of Momentum- Euler's Equation,
Conservation of Energy- Bernoulli's Equation and its Applications- Vortex Motion- Free and
Forced Vortices.
UNIT II
One Dimensional Viscous Flow: Flow Through Pipes- Hagen Poiseulle Flow- Fanning‟s
Friction Factor- Darcy's Weisbach Friction Factor- Loss of Head Due to Friction in Pipes- Flow
Through Branched Pipes, Momentum Equation- Forces Due to Pipe Bends, Sudden
Enlargement, Sudden Contraction, Flow Through Porous Media- Darcy's Equation. Two
Dimensional Viscous Flow: Navier -Stokes Equations and Solutions.
UNIT III
Laminar Boundary Layer: Momentum Integral Equation- Flow over a Flat Plate-
Displacement Thickness, Momentum Thickness and Energy Thickness.
Turbulent Boundary Layer: Laminar- Turbulent Transition- Momentum Equations and
Reynold's Stresses- Fully Developed Turbulent Flow Through a Pipe- Turbulent Boundary Layer
on a Flat Plate- Laminar Sub-Layer- Boundary Layer Separation and Control.
UNIT IV
Dimensional Analysis and Modeling Similitude: Fundamental and Derived Dimensions-
Dimensionless Groups- Buckingham- pi-Theorem- Rayleigh Method- Model Testing- Types of
Similarity- Geometric, Kinematic and Dynamic Similarities- Hydraulic Diameter.
UNIT V
Compressible Fluid Flow: Thermodynamic Relations- Continuity, Momentum and Energy
Equations- Velocity of Sound in a Compressible Fluid- Mach number and its Significance-
Limits of Incompressibility- Pressure Field Due to a moving Source of Disturbance-
Propagation of Pressure Waves in a Compressible Fluids- Stagnation properties- Stagnation
Pressure, Temperature and Density- Area Velocity Relationship for Compressible Flow- Flow
of Compressible Fluid Through Nozzles- Condition for Maximum Discharge Through Nozzles-
Variation of Mass Flow with Pressure Ratio- Compressible Flow Through a Venture Meter-
Pitot Static Tube in a Compressible Flow.
Text Books:
1. Fluid Mechanics, by A.K.Mohanty, Prentice Hall of India Pvt.Ltd.
2. Fluid Mechanics , by Douglas and swasfield , Pearson asia
43
References:
1. Fluid Mechanics and Hydraulic Machines, by R.K.Bansal, Laxmi publications.
2. Hydraulics and Fluid Mechanics by Modi and Seth, Standard book house
3. Foundations of Fluid Mechanics, by Yuan, Prentice Hall of India.
4. Fluid Mechanics and its Applications, by S.K.Gupta and A.K.Gupta, Tata McGraw Hill,
New Delhi.
5. Fluid Mechanics- S.Nagaratnam-Khanna Publishers.
6. Fluid Mechanics and Hydraulic Machines-P.K.Nag
44
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIREE306: BASIC ELECTRICAL AND ELECTRONICS ENGINEERING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
D.C circuits: KCL&KVL, Super position theorem. A.C. Circuits: Introduction of Steady State
Analysis of series A.C. Circuits, Single and balanced 3-phase Circuits. Star to delta, delta to star
conversions.
UNIT II
D.C. Machines: Types of Induced E.M.Fs, Self Inductance, Mutual Inductance. Principle of
operation Generator and Motor. Types of D.C.Generators and D.C. Motors. E.M.F Equation of
D.C Generator, Torque Equation of D.C. Motor. Swinburne‟s test, load test on DC shunt motor
and DC series motor.
UNIT III
Transformers: Transformer working principle, EMF equation of transformer, Transformer on
load, Equivalent circuit of transformer, Voltage regulation of transformer, Losses in a
transformer, Calculation of efficiency and regulation by open circuit and short circuit tests.
UNIT IV
Three phase induction motor: Construction ,types, Principle of operation, Power flow diagram,
Torque, T-S characteristics, Maximum Torque , Power stages ,Losses and efficiency, load test.
UNIT V
Introduction to Electronics and Microprocessors: Semiconductor diode, Zenor diode,
Transistor, Rectifiers and SCR (Elementary treatment only).
Fundamentals of digital electronics, Number system and codes, Logic gates, Boolean
algebra, Arithmetic-logic units, The Intel-8085 microprocessor; Architecture, Instruction set,
Addressing modes.
Text Books:
1. Principles of Electrical Engineering & Electronics, V.K.Mehta (S.Chand & Company LTD)
first edition 1996.
2. Degital logic & Computer Design , M.Morris Mano (Prontice, Hall of India Private Limited)
3. Micro Processor Architecture of Applications with 8085/8080A, Goankan. (H.S.Poplaj,
WILEY ESTERN LTD)
References:
1. A First Course in Electrical Engineering by D.P.Kothari.
2. Engineering Electronics by Ryder-McGraw Hill.
3. Micro Processors by Leventhal.
45
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME311: MECHANICAL ENGINEERING - I LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. Study the variation of Kinematic viscosity of given sample of oil with temperature using
Redwood viscometer-I
2. Study the variation of Kinematic viscosity of given sample of oil with temperature using
Redwood viscometer-II
3. Study the variation of Kinematic viscosity of given sample of oil with temperature using
Saybolt viscometer
4. Calibration of the given pressure gauge.
5. Valve timing diagram of four stroke diesel engine
6. Port timing diagram of two stroke diesel engine
7. Port timing diagram of two stroke petrol engine
8. Determine the flash point of given sample using Pensky-Martens apparatus
9. Determine of flash and fire point of a given sample using Cleavelands open cup tester.
10. Determine the moment of inertia of flywheel about its own axis of rotation.
11. Determine the moment of inertia of connecting rod and circular disc
12. Determination of Calorific value of the given Gas Fuel using Junker‟s Gas Calorimeter.
13. Determination of Calorific value of given solid fuel using Bomb Calorimeter.
14. Determination of Carbon percentage in given fuel sample using Canradson‟s Apparatus.
15. Determination of Cloud and Pour Point of given oil sample.
16. Study of boilers, various mountings and accessories
46
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME 312: MANUFACTURING TECHNOLOGY – I LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
Molding Practice:
1. Preparation of a green sand mould using Single piece pattern.
2. Preparation of a green sand mould using Split piece pattern.
3. Preparation of a green sand mould using Split Piece Pattern with Core.
4. Preparation of a green sand mould using Connecting rod pattern.
Sand testing:
5. Determination of Grain fineness number for sand sample using sieve shaker.
6. Estimation of a).The clay content and
b). The moisture content in a given sand sample.
7. Determination of Permeability of the given moulding sand specimen.
8. Determination of a).Compression strength and
b). Shear strength of a given sand specimen.
Welding practice:
9. Preparation of a Butt joint using electric arc welding.
10. Preparation of a Lap joint using arc welding.
11. Preparation of a T- joint using arc welding.
47
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIREE 313: ELECTRICAL ENGINEERING LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. Study and Calibration of Wattmeter and Energy Meter.
2. Measurement of Armature Resistance, Field Resistance and Filament Resistance.
3. Verification of KCL and KVL.
4. Superposition Theorem.
5. Parameters of choke coil
6. Load test on D.C. Shunt Motor.
7. Load test on D.C.
8. Swinburne‟s Test.series Motor.
9. O.C. Test on D.C. separately Excited DC Generator
10. Load test on single phase transformer.
11. OC and SC Tests on Transformer.
12. 3-Phase Induction Motor load Test.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Third Semester
EIRME 314: INDUSTRIAL TOUR
Hours per week: 7-10 Days Cont. Evaluation: NA
Credits: NA
48
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME401: INDUSTRIAL ENGINEERING AND MANAGEMENT
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Definition of Industrial Engineering: Objectives, Work Study, Method Study, Techniques of
Method Study - various charts, THERBLIGS, Work measurement – various methods of Work
measurements. Factors affecting productivity, Strategies for improving productivity.
UNIT II
Materials Management: Strategic importance of materials in manufacturing industries,
Inventory control models, Inventory control systems, Safety stock, selective Inventory control –
ABC, FSN, VED analysis.
Quality Management: Definition of quality, various approaches, Concepts of quality assurance
systems, Statistical quality control (SQC), Variables & Attributes, Charts, Acceptance sampling,
OC curve, Introduction to TQM & ISO-9000.
UNIT III
Production Planning and Control: Objectives, Types of productions, Production cycle, product
design and development, process planning, Forecasting, Functions of production control.
Plant Layout & Material Handling: Plant layout and location. Types of layouts, principles,
concept of unit load, selection of material handling equipment.
UNIT IV
Industrial Management: Concepts, Principles of management, Growth of management thought,
Functions of management, principles of organizations, Types of organizations.
UNIT V
Industrial Relations: Industrial disputes, Settlement of industrial disputes, Trade unions,
Industrial dispute act 1947 and factories act 1948. Conflict management in organizations.
Text Books:
1. Introduction to Work Study, ILO, Geneva, International labour office publishers, 3rd
ed..
2. Industrial Engineering and Management by O P Khanna.
References:
1. Principles of management by Koontz & Donnel
2. Production and operations management by Evcret Adam and Ronald Ebert.
3. Operations management by John Mcclain & Joseph Thames.
4. Industrial Engineering and Production Management by Telsay, S Chand & Co
5. Production & Operations Management by Chary, TMH, New Delhi.
49
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME 402: MANUFACTURING TECHNOLOGY – II
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Mechanics of Metal Cutting: Terms and Definitions, Chip Formations, Forces Acting on the
Cutting Tools and their Measurement, Chip Thickness, Theory of Ernest and Merchant, Theory
of Lee and Shaffer, Friction and Temperature in Metal Cutting, Measurement of Temperature on
Tool Rake Face- Techniques, Nomenclatures of Cutting Tools, Tool Designation Systems-ASA,
ORS, Tool Angles, Tool Materials, Tool life – Taylor's Equation, Mechanism of Tool Wear,
Machinability, Cutting Fluids.
UNIT II
Machine Tools using Single Point Tools: Lathes Types-Specifications, Lathe Accessories and
Attachments, Different Operations, Boring Machines- Types, Jig-Boring, Shaper- Mechanisms,
Operations, Planar Mechanisms, Operations, Speeds, Feeds, Calculation of Metal Removal,
Economics of Single Point Cutting Tool.
UNIT III
Machine Tools using Multi Point Tools: Drilling Machine, Drill Press -Types, Operations,
Milling Machines; Vertical and Horizontal Attachments, Indexing-Methods, Operations,
Broaching Machine, Specifications, Operations, Calculation of Metal Removal, Production of
Gears- Methods.
UNIT IV
Abrasive Machining: Abrasive wheels- Manufacturing, Specifications, Grinding Machines-
Classification, Precision Grinding Processes- Polishing, Buffing, Honing, and Lapping.
UNIT V
Non Conventional Machining Processes: USM- Ultra sonic machining, AJM- Abrasive jet
machining, EDM- electric discharge machining, EBM-Electron beam machining, CHM-
Chemical machining, ECM-Electro Chemical machining, LBM-Laser beam machining -
Applications, Advantages, limitations.
Text Books:
1. Workshop Technology, by Raghuvamsi, Khanna Publishers
2. A Text book of Production Technology by P.C.Sharma, S.Chand & Company Ltd
References:
1. Work Shop Technology by W.A.J Chapman
2. Metal Cutting Theory & Practice, by Bhattacharya. A, Central book publishers
3. Manufacturing Science, by Ghosh & Mallik
4. Manufacturing Engineering and Technology by Kalpak Jian, Pearson education.
50
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME403: APPLIED THERMODYNAMICS – II
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Steam Nozzles: Type of Nozzles- Flow through Nozzles- Condition for Maximum Discharge-
Nozzle Efficiency- Super Saturated Flow in Nozzles- Wilson‟s line -Relationship between Area
Velocity and Pressure in Nozzle Flow- Steam Injectors.
UNIT II
Steam Turbines: Classification of Steam Turbines- Impulse Turbine and Reaction Turbine-
Compounding in Turbines- Velocity Diagrams in Impulse and Reaction Turbines- Degree of
Reaction- Condition for Maximum Efficiency of Reaction Turbines- Losses in Steam Turbines-
Reheat Factor- Governing of Turbines.
UNIT III
Performance of I.C. Engines: Testing and Performances of I.C. Engines- Problems - Normal
Combustion and Abnormal Combustion- Importance of Flame Speed and Effect of Engine
Variables, types of Abnormal Combustion Pre-ignition and Knock. C.I. Engines- Stages of
Combustion- Delay Period and its Importance- Effect of Engine Variables, Diesel Knock, Fuel
Requirements and Fuel Rating, Anti-Knock agents.
UNIT IV
Gas Turbines: Simple Gas Turbine Plant- Ideal Cycle, Closed Cycle and Open Cycle for Gas
Turbines, Constant pressure cycle, constant volume cycle, Efficiency, Work Ratio and Optimum
Pressure Ratio for simple Gas Turbine Cycle. Parameters of Performance- Actual Cycle,
Regeneration, Inter-Cooling and Reheating.
UNIT V
Refrigeration: Bell Coleman Cycle, Vapor Compression Cycle – Effect of Suction and
Condensing Temperature on Cycle Performance. Properties of Common Refrigerants, Vapor
Absorption System, Electrolux Refrigerator. Comparison of various Refrigeration Methods
Text Books:
1. Thermal Engineering, by M.L.Mathur and F.S.Mehta, Jain Brothers.
2. Treatise on heat engineering by P.Vasandani and D.S.Kumar, Metropolitan Co.Pvt.Ltd.
References:
1. Thermal Engineering, by R.K.Rajput., Laxmi Publications
2. Thermal Engineering by P.L.Ballaney
3. I.C.Engines, by Mathur and Mehta
4. Gas Turbines, by Cohen , Rogers and Sarvana Mutto, Addison Wesley – Long Man
5. I.C. Engines by V. Ganesan.
6. Refrigeration and Air- conditioning by C.P.Arora., Tata McGraw hill.
51
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME404: MECHANICS OF SOLIDS-II
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Fixed Beams: Fixing moments for a fixed beam of uniform section, Moment area method,
Macaulay‟s method and strain energy method, Effect of sinking support, slope and deflection.
UNIT II
Continuous beams: Analysis, Reaction at the supports, Clapeyron‟s three moment equation and
strain energy method, Effect of sinking of supports.
UNIT III
Columns and Struts: Columns with one end free and the other fixed, Both ends fixed,
One end fixed and other hinged, Limitation of Euler's formula, Column with initial
curvature, Column carrying eccentric load, Laterally loaded columns, Empirical formulae.
UNIT IV
Thin Cylinders and Spherical Shells: Stresses and strains (principal stress, principal strain,
shear stress, shear strain and volumetric strain) in thin cylinders, thin spherical shell; wire wound
cylinders
Thick cylinders: Thick cylinders Coursed to internal and external pressure and compound
cylinders; different stresses induced; Lames equation, stresses due to shrink fit.
UNIT V
Bending of Curved Bars: Stresses in bars of circular, rectangular and trapezoidal sections.
Stresses due to rotation: Wheel rim, disc of uniform thickness, disc of uniform strength.
Text Books:
1. Strength of materials by Dr. Sadhu Singh, Kanna Publications
2. Elements of Strength of materials by SP Timoshenko and D.H. Young, East-West press Pvt.
Ltd
3. Strength of materials by SS Rattan, Tata McGraw-Hill
References:
1. Analysis of Structures, Vol. 1, 1993 edition, by Vazirani and Ratwani.
2. Mechanics of solids by Crandal, Dahl and Lardner.
3. Mechanics of Materials by Beer and Johnson, McGraw-Hill
52
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME405: THEORY OF MACHINES – I
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Mechanisms and machines: Introduction, mechanism and machine, rigid and resistant bodies,
link, kinematic pair, degrees of freedom, classification of kinematic pairs, kinematic chain,
mechanism and structure, classifications of mechanisms, equivalent mechanisms, four bar
mechanism, inversions of four bar mechanism, slider crank chain and double slider crank chain.
Lower pairs: Introduction, pantograph, straight line mechanism, automobile steering gears,
engine indicators, types of steering gear, Hooke‟s joint, double Hooke‟s joint.
UNIT II
Velocity Analysis: Introduction, absolute and relative motions, motion of a link, angular velocity
of links, velocity of rubbing, slider crank mechanism, crank and slotted lever mechanism,
instantaneous center method, number of instantaneous centers, Kennedy‟s theorem, angular
velocity by instantaneous center method, centroid.
Acceleration analysis: Acceleration of a link, four bar mechanism, angular acceleration of links,
acceleration of intermediate and offset points, slider crank mechanism, and Coriolis acceleration
component, crank and slotter lever mechanism.
UNIT III
Cams: Introduction, types of cams, types of followers, motion of the follower,uniform velocity,
SHM uniform acceleration and retardation, profile of cams, cams with specified contours–
tangent cam with roller follower and Circular arc cam with Flat-Faced follower.
UNIT IV
Gears and Gear trains: Introduction and classification of gears, gear terminology, law of
gearing, velocity of sliding, forms of teeth, cycloidal profiles, involute profiles, path of contact,
arc of contact, numbers of pairs of teeth in contact interference in volute gears, minimum number
of teeth, interference between rack and pinion, under cutting, helical and spiral gears, velocity
ratios, and centre distance of helical gears, helical gear forces and efficiency, worm and worm
gears, bevel gears. Simple gear trains, compound gear trains, reverted gear train, epicyclic gear
train, analysis and torques in epicyclic gear trains, sun and planet gear, differential gear.
UNIT V
Computer aided analysis of mechanism: Introduction, Four Bar mechanism,slider crank
mechanism, coupler curves.
Graphical and computer aided synthesis of mechanisms: Pole, Relative pole, design of
mechanisms by Relative pole method, Inversion method, design of mechanisms by Inversion
method, computer aided synthesis of mechanisms.
53
Text Books: 1. Theory of machines- S.S.Rattan, Tata Mc Graw Hill Publications.
References:
1. Theory of Machines by Thomas Bevan.
2. Theory of Machines by W.G.Green.
3. Theory of Machines by R.S. Khurmi & J.K.Gupta
4. Theory of Machines by Dr. Jagadishlal
5. Theory of Machines by P.L.Ballaney
6. Design of Machinery by R.L.Norton.
54
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME406: HYDRAULIC MACHINES & SYSTEMS
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Impact of jets: Hydrodynamic force of jets on stationary and moving flat, inclined and curved
waves, jet striking centrally and at tip – velocity triangles at inlet and outlet – expressions for
work done and efficiency – angular momentum principle.
UNIT II
Hydraulic Turbines: Classification- Pelton wheel- Reaction turbines- Inward and outward
radial flow reaction turbines- Francis turbine- Axial flow reaction turbine- Kaplan turbine-
Draft tube- Types- Theory- and efficiency of draft tube.
Performance of Turbines: Specific Speed: Determination- Significance- Unit quantities- Unit
speed- Unit discharge and unit power- Characteristic curves of hydraulic turbines- Constant
head curves- Constant speed curves and Iso-efficiency curves- Governing of turbines.
UNIT III
Centrifugal Pumps: Main parts- Efficiency- Minimum speed for starting- Multi-stage
centrifugal pumps- Specific speed of a centrifugal pump- Priming of a centrifugal pump-
Characteristic curves- Main, Operational and constant efficiency curves- Cavitation-
Effects- Cavitations in Hydraulic machines.
UNIT IV
Reciprocating Pumps: Main parts- Classification- Velocity and acceleration variation in
suction and delivery pipes due to piston acceleration- Effect of variation of velocity on
friction in suction and delivery pipes- Effect of acceleration in suction and delivery pipes on
indicator diagram- Effect of friction- Maximum speed of reciprocating pump- Air vessels.
UNIT V
Hydraulic Devices: Hydraulic press - Hydraulic accumulator- Differential hydraulic
accumulator- Hydraulic intensifier- Hydraulic ram- Hydraulic lift- Hydraulic crane- Fluid
coupling- Hydraulic torque converter. Introduction to open and closed loop systems,
Hydraulic and Pneumatic systems.
Text Books:
1. Fluid Mechanics and Hydraulic Machinery, by R.K.Bansal, Laxmi publications.
2. Hydraulics and Fluid Mechanics by Modi and Seth, Standard book House
References:
1. Fluid Flow Machines, by N.S.Govinda Rao, Tata McGraw Hill publishing company Ltd.
2. Fluid Mechanics and Hydraulic Machines by K.R.Arora
3. Fluid Mechanics and Hydraulic Machines by R.K.Rajput
4. Elements of Hydraulic Machines & Fluidics by Jagadish Lal.
55
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME411: MECHANICAL ENGINEERING-II LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. Conduct a load test on Research Engine with Petrol fuel and draw various
performance curves.
2. Conduct a load test on Research Engine with petro- blends and draw various
performance curves
3. Conduct a load test on Research Engine with Bio fuel and draw various performance
curves
4. Conduct a load test on Research Engine with diesel and bio fuel blends and draw
various performance curves
5. Conduct an experiment on two-stage reciprocating air compressor to determine
various efficiencies.
6. Conduct Morse test on high-speed four-stroke multi cylinder S.I MARUTI Engine to
determine F.P and Mechanical efficiency.
7. Conduct Heat Balance sheet on high-speed four-stroke multi cylinder MARUTI
SUZUKI make S.I Engine at ½ and ¾ loads.
8. Conduct a load test on Four stroke Variable Compression Engine S.I.Engine and
draw various performance curves
9. Conduct a load test and Heat balance sheet on Four stroke Kirloskar diesel Engine
draw various performance curves
10. Conduct an experiment on vapor compression refrigerator to determine C.O.P
11. Study of dynamic balancing machine
12. Study of Automotive Components
56
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME412: MECHANICS OF SOLIDS LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. To study the Stress Strain Characteristics (Tension & Compression) of Metals by using
UTM.
2. To study the Stress Strain Characteristics of Metals by using Hounsefield Tensometer.
3. Determination of Compressive Strength of wood
4. Determination of hardness using different hardness testing Machines- Brinnels, Vickers,
and Rockwell‟s.
5. Impact Test by using Izod and Charpy Methods.
6. Deflection test on Beams using UTM.
7. Tension Shear Test on MS Rods.
8. To find Stiffness and Modulus of Rigidity by Conducting Compression Test on Springs.
9. Torsion Test on Circular Shafts.
10. Buckling of Sand
11. Punch Shear Test , Hardness Test and Compression Test by using Hounsefield
Tensometer.
57
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fourth Semester
EIRME413: MACHINE DRAWING LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
Screw threads: Definitions, V-Threads, Square Thread, Conventional Representation of
Threads, Right Hand and Left Hand Threads.
Screw fastenings: Introduction, Hexagonal Nut, Square Nut, Flanged Nut, Dome Nut, Ring Nut,
Washer, Types of Bolts, Lock Nut, Castle Nut, Eye Foundation Bolt, Rag Bolt Lewis Bolt and
Spanner.
Keys and Cotter Joints: Introduction, Taper Key, Sunk Taper Key, Round Key, Saddle Key,
Feather Key, Splined Shaft, Woodruff Key, Socket and Spigot Joint, Knuckle Joint.
Shaft Couplings: Box and Split Muff Coupling, Flanged, Universal and Oldham‟s Coupling.
Shaft Bearings: Solid Bearing, Bushed Bearing, Foot Step Bearing and Pedestal Bearing.
Assembly Drawings: Stuffing Box of Steam Engine, Eccentric of Steam Engine, Connecting
Rod of an IC Engine, Screw Jack, Swivel Bearing, Tool Post of Lathe Machine.
Note: 1)The above Mechanical Components can be Drawn using Mechanical Drafting
packages like AutoCAD/MDT/CATIA.
2) Drawings as per IS.
3) All Drawings are in 2-D in which one chapter should be drawn in 3-D.
Text Books:
1. Machine Drawing by N.D.Bhatt, V.M.Panchal, 42nd
edition, Charotar Publishing House
2007.
2. Machine Drawing by R.K Dhawan 2nd
edition, S.Chand and Co Ltd., New Delhi.
References:
1. Machine Drawing by K.L.Narayan, P.Kannaiah and K.Venkata Reddy, 2nd edition, New
Age publications 2003.
2. Engineering Graphics with AutoCAD 2002 by James D Bethune, First Indian edition,
Pearson Education 2003.
58
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME501: THEORY OF MACHINES – II
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Static Force Analysis: Introduction, Static Equilibrium, Equilibrium of Two-force and Three-
force members, Member with Two force and a torque, Force convention, free body diagrams,
Superposition.
Dynamic force Analysis: Introduction, D‟Alemberts principle, Equivalent Offset inertia force,
Dynamic analysis of Four bar and Single slider mechanisms, Klein‟s construction, velocity and
acceleration of piston, angular velocity and angular acceleration of connecting rod, piston effort,
turning moment on crank shaft, Inertia of connecting rod, Inertia forces in reciprocating
Engines(Graphical method).
UNIT II
Gyroscope: Introduction, Precessional angular motion, gyroscopic couple, effect of gyroscopic
couple on an aero plane, effect of gyroscopic couple on a naval ship during steering, gyroscopic
couple on a naval ship during pitching, gyroscopic couple on a naval ship during rolling, stability
of a four wheel drive moving in a curved path, stability of a two wheel vehicle taking a turn.
UNIT III
Governors: Introduction, types of governors, Watt governor, Porter governor, Proell governor,
Hartnell governor, Wilson-Hartnell governor, Spring controlled gravity governor, Inertia
governors, Sensitiveness of governor, Hunting, Isochronism, Stability, effort of governor, power
of governor, controlling force.
UNIT IV
Balancing: Introduction, Static balancing, dynamic balancing, balancing of several masses in
same planes, balancing of several masses in different planes, Balancing of Reciprocating masses,
balancing of locomotives, balancing of inline engines, balancing of V-engines.
UNIT V
Vibrations: Introduction, Definitions, Types of vibrations- Natural frequencies of free
longitudinal vibrations of systems having single degree of freedom- Equilibrium method-Energy
method and rayleghy‟s method. Frequency of damped vibration with damping-magnification
factor or dynamic magnifier.
Transverse and Torsional Vibrations: Natural frequency of free transverse vibrations due to
point load and UDL acting over a simply supported shaft- transverse vibration for a shaft Course
ed to number of point loads-energy method- dunkerley‟s method, critical speed of a shaft.
Natural frequency of free torsional vibrations- free torsional vibrations of a single rotor system,
two rotor and three rotor system and gear system.
59
Text Books:
1. Theory of machines by SS Rattan, Tata Mc Graw Hill publications.
References:
1. Theory of Machines by Thomas Bevan.
2. Theory of Machines by W.G.Green.
3. Theory of Machines by R.S. Khurmi & J.K.Gupta
4. Theory of Machines by Dr. Jagadishlal
5. Theory of Machines and Mechanisms by PL Ballaney
6. Theory of Machines and Mechanisms by Amitaba Ghosh and Ashok kumar Mallik(EWP)
7. Design of Machinery by R.L.Norton
60
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME502: METROLOGY
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Linear Measuring Instruments: Vernier height gauge, Vernier depth gauge, Depth
Micrometer, Dial Gauge, Slip Gauges.
Angular Measuring Instruments: Universal Bevel Protector, Optical Bevel Protector, Sinebar,
Angle gauges, Precission level, Autocollimator, Angle Dekkor.
UNIT II
Comparators: Characteristics of comparators, Types of comparators- Mechanical, Pneumatic,
Optical level and Electrical. Advantages and disadvantages of comparators.
Straightness, Flatness and Roundness measurement: Introduction, monochromatic light,
interference of light, conditions for interference of light waves. Flatness .General description of
Optical Flats. Interferometry applied to flatness Testing. N.P.L. Flatness interferometer.
Straightness Measurement, Roundness measurement- Tool Maker‟s Microscope
UNIT III
Limits, Fits, Tolerances & Limit Gauges: ISO system of limits, fits, tolerances as per IS 919,
hole base system, shaft base system, interchangeability, selective assembly, plain limit gauges;
Plug gauges, Ring gauges.
UNIT IV
Metrology of Screws & Gears: Metrology for screw threads, measurement of major diameter,
minor diameter, effective diameter. Measurement of spur gear, pitch, backlash, tooth thickness.
Miscellaneous Gauges: Radius gauges, Screw, pitch gauges, gauges for external threads. Feeler
gauges.
UNIT V
Measurement of surface finish: methods of measuring surface finish, surface texture
Machine tool acceptance tests: Acceptance tests for lathe, drilling machines.
Text Books:
1. I.C. Gupta, „A Text Book of Engineering Metrology‟, Dhanpat Rai & sons, Delhi
2. R.K.Jain, Jain „Engineering Metrology‟, Khanna Publishers.
References:
1. A.S. T.M.E. Hand Book of Industrial Metrology, Prentice Hall of India, New Delhi
2. Technology of the metal Trade, Wiley Eastern Limited.
3. Engineering Metrology by Mahajan, Khanna Publishers.
4. CAD/CAM by M.P.Groover
61
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME503: POWER PLANT ENGINEERING
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Steam Power Plants: General layout, Power plant cycles, Coal-handling, storing,
preparation and supply. Various stokers. Draft systems, chimney including calculations. Flue
gas testing and indicators (mechanical, electrical and chemical). Boilers: Mountings and
accessories. High pressure and high duty forced circulation boilers and modern trends in Boiler
design. Boiler performance.
UNIT II
Nuclear power plants: Classification of reactors, Fuels, Fuel moderator and coolant,
Control and safety rods, Special properties of structural materials required, Induced radio-
activity, Gas cooled reactors, Radiation hazards and shielding, Radioactive waste disposal.
Wind Energy: Introduction ,classification , horizontal axis wind turbine (HAWT) - vertical axis
wind turbine(VAWT) - rotor design considerations - blade profile - 2/3 blades and teetering –
coning - upwind / downwind - power regulation - Yaw system - inverters.
UNIT III
Solar Energy: solar radiation, its measurement and prediction. Solar angles - day length, angle
of incidence on tilted surface. Flat plate collectors: liquid and air type.
Hydro Electric Plants: Selection of site, Hydrology, Hydrometric survey rainfall, Catchment,
Reservoir, Run-off flow and fall, Storage and pondage. Losses due to percolation, evaporation
and transpiration. General layout of the plant. Different types of plants. Low, medium and high
head plants and pump storage plants. Types of Spillways and Dams.
UNIT IV
Fuel cell: Principle of operation of an acidic fuel cell, Reusable cells, Ideal fuel cells, Other
types of fuel cells, Comparison between acidic and alkaline hydrogen-oxygen fuel cells,
Efficiency and EMF of fuel cells, Operating characteristics of fuel cells, Advantages of fuel cell
power plants, Future potential of fuel cells.
UNIT V
Geo, OTEC -Thermal Energy Sources: Introduction –Geo thermal sources – applications
for thermal and electricity generation – ocean energy - Introduction – OTEC conversion –
thermal electric power generation - energy utilization – site selection – potential Impacts.
Power Plant Economics: Capacity factor, Load factor, Diversity factor, Peak load
consideration, Factors governing capacity of plants. Cost of power plant, Cost of erection.
Operating and maintenance expenses, Cost of production, distribution of power and
determination of rates.
62
Text Books:
1. Power plant engineering by P.K.NAG
2. A Text Book of Power Plant Engineering by R.K. Rajput.
3. Power Station Engineering and Economy, by Benhaedt G.A. Skrotzki, William A.
Vopat, McGraw-Hill Book Company, Inc.
4. Power plant engineering by G.R.Nagpal.
5. Non-Conventional energy resources by G.D.RAI, Khanna publishers.
References:
1. Solar Power Engineering by B.S.Magal, Tata McGraw-Hill publishing Co. New Delhi.
2. Modern Power Plant Engineering, by Joel Weisman, Roy Eckart, Prentice Hall of India
Pvt.Ltd., New Delhi.
3. Fundamentals of Nuclear Power Engineering, by D.K. Singhai, Khanna Publishers, Delhi-6.
4. Sukhatme, S.P., Solar Energy, Tata McGraw Hill, 1984.
5. Twidell, J.W. and Weir, A., Renewable Energy Sources, EFN Spon Ltd., 1986.
6. Heat Engineering, I.T. Shvets et al, MIR Publishers, Moscow.
7. Hart, A.B., and Womack, G. J., Fuel Cells: Theory & Applications, Prentice Hall, 1997.
63
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME504: MACHINE DESIGN
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Mechanical engineering design;Traditional design methods. Design synthesis. Design
considerations and standards.Engineering materials classification and selection. BIS designation
of steels.
Design against static loads:Modes of failure, Factory of safety, Axial, bending and torsional
stresses. Theories of failures- rankines theory, Trescas theory, Hekys theory,Vonmises theory
Fluctuating and fatigue stresses -Stress concentration factors, endurance limit, notch
sensitivity. Soderberg, Goodman and modified Goodman diagrams, fatigue design under
combined loading.
UNIT II
Keys and Couplings: design of Keys, square keys , rectangular keys, kenedy key and woodruff
key
Couplings- Rigid couplings – muff couplings, flange coupling . flexible coupling- bushed pin
coupling, Universal coupling
Design of shafts: Strength basis and rigidity bases, Equivalent bending and twisting.
UNIT III
Design of Sliding contact bearings: Lubrication modes, Temperature effect on viscosity,
Journal bearing design, Bearing modulus, McKee equations, Heating of bearings,
Design of Rolling contact bearings - Static and dynamic load capacity, Equivalent bearing
load, Load-life relationships, Load factor, Selection of bearings from manufacturers catalogue.
UNIT IV
Design of clutches- uniform pressure theory, uniform wear theory, design of friction clutches-
single plate multi-plate clutches.
Brakes– Block brakes- external, internally expanded, Band brakes, Band and block brake
UNIT V
Design of Gears; Classification of gears Standard tooth systems, Spur, Helical, Bevel and
Worm gears, Terminology of each, Tooth failure, Face width an beam strength, Lewis equation,
Design for dynamic and wear loads, Force analysis of Bevel and Worm gears, Thermal
design considerations of worm gears.
Text Book:
1. Design of Machine Elements by V.B. Bhandari, TMH Co. Ltd., 1st ed.
References:
1. Machine Design by R.K. Jain, Khanna publications, 4th ed.
2. Machine Design by R.S. Khurmi & J.K.Gupta, S. Chand &Company Ltd , 1st ed.
3. Machine Design by Pandya and Shah, Charator publishing house, 15th
ed.
64
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME505: INSTRUMENTATION AND CONTROL SYSTEMS
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Introduction to Instrumentation: Process of measurement, Static performance characteristics,
Dynamic performance characteristics, Transducer elements, Intermediate elements, and
Indicating and recording elements.
Motion measurement: Relative motion measurement, absolute motion measurement, calibration
of motion measuring devices.
UNIT II
Force measurement: Hydraulic load cell, Pneumatic load cell, Elastic force devices, calibration.
Torque and power measurement: Transmission dynamometers, Driving type dynamometers,
Absorption dynamometers. Temperature measurement: Non-electrical methods, electrical
methods, Radiation methods. Vibration measurement: velocity & acceleration measurement.
Vibration transducers, signal conditioning elements. Display and recording elements. Vibration
meters and analyzers
UNIT III
Control systems: Introduction, Open loop and closed loop systems, feed back and its effects.
Transfer function, block diagram and signal flow graph: Impulse response and transfer functions
of linear systems, block diagrams.
UNIT IV
Mathematical modeling of Physical systems: Equations of electrical networks, modeling of
mechanical system elements, equation of mechanical systems. State- variable analysis of linear
dynamic systems; Matrix representation of state equations, state transition matrix, state
transition equation, relationship between state equations and high- order differential equations,
relationship between state equations and transfer functions, Characteristic equation, eigen values,
and eigen vectors.
UNIT V
Time-domain analysis of control systems: Typical test signals for the response of control
systems, Time-domain performance of control systems- stability of control systems- stability
characteristic equation and the state transition matrix, methods of determining stability of linear
control systems, Routh-Hurwitz criterion. Introduction to Frequency-domain analysis of control
systems, bodo plots, Nyquist plots.
65
Text Books:
1. Mechanical Measurements by Sirohi and Radha Krishnan.
2. Modern Control systems by Benjamin .C. kuo
References:
1. Experimental Methods for Engineers, by J.P.Holman, McGraw-Hill.
2. Instrumentation by Dobelion.
3. Mechanical and Industrial measurements by R.K.Jain
4. Instrumentation measurements and analysis by B.C.Nakra and K.K. Chaudhry, Tata Mc
Graw Hill
5. Automatic Control by Droff.
6. Control systems Engineering by Nagrath and Gopal
66
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME506: OPERATIONS RESEARCH
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Development: History, and Development of Operations Research, OR Models.
Linear Programming: Introduction to LP- Formulation of Linear Programming Problems,
Graphical Method; Simplex Method, Artificial variable technique, Duality, Dual Simplex
method.
UNIT II
Transportation: Formulation methods for finding Initial Solution, Optimal solution.
Unbalanced transportation problems.
Assignment: Formulation optimal solution, Traveling salesman problem.
UNIT III
Queuing Theory: Introduction, Queuing systems; Characteristics of Queing models, Different
queuing models
Sequencing: Introduction, Terminology, problems with n-jobs and two machines, ,
problems with n-jobs and three machines, problems with n-jobs and m-machines, graphic
solution.
UNIT IV
Replacement and Maintenance: Introduction, Replacement of items that deteriorate with time -
value of money unchanging and changing, Replacement of items that fail completely.
Theory of games: Introduction, Two-person zero-sum games, The Minimax and Maximin
principle, Games without saddle points - Mixed strategies, 2xn and mx2 Games - Graphical
solutions, Dominance property
UNIT V
Inventory: Introduction, Inventory costs, Economic order quantity (EOQ) EOQ Models,
Production inventory model; Inventory models with shortages quantity discounts
Project Management: Introduction, Project scheduling by CPM and PERT; Steps involved in
the application of CPM and PERT.
Text Books:
1. A Text Book of Operation Research, by D.S.Hira,P.K.Gupta
2. Operations Research, by V.K.Kapoor
References:
1. Operations Research Methods and Problems, by M.Sasiene, A.Yespal and
L.Friedman.(John Wiely)
2. Operations.Reasearch., by S.D.Sharma.(Kedarnadh Ramnadh & Co.,
67
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME511: FLUID MECHANICS AND MACHINERY LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. To study the general behavior of reciprocating pump and to compute percentage of slip,
overall efficiency and coefficient of discharge of the pump working under constant speed.
2. To study the procedure for conducting load test on Pelton wheel
3. Calibration of flow nozzle.
4. Calibration of Orifice meter
5. To study the general method of calibration of venturimeter.
6. To study the Calibration procedure of the given Triangular notch (V - Notch)
7. Determine the coefficient of discharge of a small orifice
8. Determine the coefficient of discharge of a mouth piece
9. Conduct a load test on a Francis turbine and draw various characteristic curves.
10. Determine the overall efficiency of a centrifugal pump and draw various performance
curves.
11. Performance characteristics of hydraulic ram
12. Performance characteristics of Kaplan turbine
13. Resistance characteristics of pipes.
14. Pressure distribution and drag characteristics of a cylinder and aerofoil in a wind tunnel.
68
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIRME512: MANUFACTURING TECHNOLOGY -II LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. Lathe-Step turning, Chamfering, Knurling.
2. Lathe-Taper turning, Chamfering, Knurling.
3. Lathe-Thread cutting, Parting off, Chamfering, Knurling.
4. Lathe-Eccentric turning.
5. Lathe-Off set turning.
6. Measurement of cutting tool temperature in turning using thermocouple.
7. Milling- Round to Hexagonal nut cutting using Direct indexing method.
8. Milling- Spur gear cutting using Simple indexing method.
9. Milling- Spur gear cutting using Differential indexing method.
10. Shaping- Round to square cutting, V-groove cutting.
11. Shaping- Round to square cutting, Semi hexagonal cutting.
12. Planning practice and slotting practice.
13. Force measurement using dynamometers on milling, drilling, lathe machines.
14. Grinding: Grinding a single point cutting tool as per given signature.
15 .Effect of speed and feed on surface grinding.
69
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Fifth Semester
EIREG513: ENGLISH COMMUNICATION SKILLS LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
Concept and importance of communication. Developing Communicative abilities. Paper
Presentation – Planning, preparation and Presentation using Audio-Visual aids. Proposals and
Research Reports. Oral Presentation:
a. Group Discussion.
b. Interviews
c. Conducting a meeting.
d. Telephone Etiquette.
Text Books:
1. Himstreet, William C., Gerald w.Maxwell, Mary Jean Onorato. Business Communications. A
Guide to effective writing, speaking and listening. Gelencoe publishing company. California
1982.
2. Murphy, Hurta A etal, Effective Business communications, The McGraWHill companies Inc.
1997.
3. Thill, John V., Bove‟e, Courland L. Excellence in Business Communication. McGraw Hill
Inc. 1996.
4. Lesitar & Pettit. Report writing for Business. Irwin – McGraw Hill. 1995. Tenth Edition.
5. Paulery and Riordan. Technical report writing today. Houghton Mifflin company. 1999.5th
edition. Reprint.
70
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME601: COMPUTATIONAL METHODS IN ENGINEERING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Modeling, Computers, and Error Analysis: Mathematical Modeling and Engineering Problem
Solving, Approximations and Round-Off Errors, Truncation Errors and the Taylor Series.
Roots of Equations: Bracketing Methods – Bisection Method, False Position Method,
Incremental searches and Determining Initial Guesses; Open Methods – Fixed Point Iteration,
Newton-Raphson Method, Secant Method; Roots of Polynomials – Muller‟s Method, Bairstow‟s
method; Application to practical problems – Ideal and Nonideal gas laws, Vibration Analysis.
UNIT II
Linear Algebraic Equations: Gauss Elimination – Solving Small Numbers of Equations, Naïve
Gauss Elimination, Pitfalls, Techniques for improving Solutions, Nonlinear Systems of
Equations, Gauss-Jordan; LU Decomposition and Matrix Inversion, Special Matrices and Gauss-
Seidel, Application to practical problems – Analysis of a Statically Determinate Truss, Spring
Mass Systems.
UNIT III
Numerical Differentiation and Integration: Newton-Cotes Integration Formulas – Trapezoidal
Rule, Simpson‟s Rules, Integration with Unequal Segments, Open Integration Formulas,
Multiple Integrals; Integration of Equations - Newton-Cotes Algorithms for Equations, Romberg
Integration, Gauss Quadrature, Improper Integrals; Numerical Differentiation – High Accuracy
Differentiation Formulas, Richardson Extrapolation, Derivatives of Unequally spaced Data;
Application to practical problems – Integration to Determine the Total Quantity of Heat,
Computation of Work.
UNIT IV
Ordinary Differential Equations: Runge-Kutta Methods – Euler‟s Method, Improvement of
Euler‟s Method, Runge-Kutta Methods, Systems of Equations, Adaptive Runge-Kutta Methods;
Stiffness and Multistep Methods, Boundary-Value and Eigenvalue Problems, Application to
practical problems – The Swinging Pendulum.
UNIT V
Partial Differential Equations: Finite Difference: Elliptic Equations – The Laplace Equation,
Solution Techniques, Boundary Conditions, The Control Volume Approach; Finite Difference:
Parabolic Equations – The Heat Conduction Equation, ExplicitMethods, a Simple Implicit
Method, The Crank-Nicolson Method; Application to practical problems - Finite-Element
Solution of a Series of Springs,
71
Text Book:
1. Numerical Methods for Engineers, S. C. Chapra and R. P. Canale, Tata McGraw-Hill
Company Ltd.
References:
1. Applied Numerical Methods with MATLAB for Engineers and Scientists, S. C. Chapra,
McGraw-Hill Company Ltd.
2. Applied Numerical Methods for Digital Computation, M. L. James, G. M. Smith, J. C.
Wolford, Harper & Row Publishers
72
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME602: HEAT AND MASS TRANSFER
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Introduction: Basic modes of heat transfer- Rate equations- Generalized heat conduction
equation in Cartesian, Cylindrical and Spherical coordinate systems. Steady state heat
conduction solution for plain and composite slabs, cylinders and spheres- Critical thickness of
insulation- Heat conduction through fins of uniform and variable cross section- Fin effectiveness
and efficiency.
Unsteady state Heat Transfer conduction: Transient heat conduction- Lumped system
analysis, and use of Heisler charts.
UNIT II
Convection: Free and Forced convection- Continuity, momentum equations, Boundary layer
theory concepts-energy equations- Dimensional analysis-Approximate solution of the
boundary layer equations- Laminar and turbulent heat transfer correlation- Momentum
equation and velocity profiles in turbulent boundary layers- Application of dimensional
analysis to free and forced convection problems- Empirical correlation.
UNIT III
Radiation: Black body radiation- radiation field, Kirchoff's laws- shape factor- Stefan
Boltzman equation- Radiant heat exchange, parallel and perpendicular surfaces- Radiation
shields.
UNIT IV
Heat Exchangers: Types of heat exchangers- Parallel flow- Counter flow- shell & tube heat
exchangers - Cross flow heat exchangers- Overall heat transfer coefficient- LMTD and
NTU methods- Fouling in heat exchangers- Heat exchangers with phase change.
UNIT V
Boiling and Condensation: Different regimes of boiling- Nucleate, Transition and Film boiling.
Condensation: Laminar film condensation- Nusselt's theory- Condensation on vertical flat plate
and horizontal tubes- Drop wise condensation.
Mass Transfer: Conservation laws and constitutive equations- Fick's law of diffusion-
Equimolal counter diffusion- Mass transfer coefficient.
73
Text Books:
1. Heat Transfer, by J.P.Holman, Int.Student edition, McGraw Hill Book Company.
2. Fundamentals of Heat and Mass Transfer- Incropera and Dewitt
References:
1. Heat and Mass Transfer- Arora and Domkundwar
2. Analysis of Heat Transfer by Eckert and Drake, Intl student edition Mcgraw hill.
3. Essential of Heat Transfer by Christopher A. Long
4. Heat transfer by Sukhatme
5. Heat transfer by Yunus A Cengel
74
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME603: PRODUCTION PLANNING AND CONTROL
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Introduction: Objectives of production planning and control, definitions, functions of
production planning and control, organization of production planning and control department,
internal organization of department.
Forecasting: Forecasting models, Aggregate production planning, master production scheduling,
materials requirements planning.
UNIT II
Inventory Control: Objectives, scope of the problem, economic and social complications of
inventory management, control systems approach, limitations of inventory control. Functions of
inventory, demand and production characteristics. Measures of inventory performance.
Systematic control of inventory: Fixed order quantity systems, fixed interval systems,
(s, S) systems, classification of items in inventory. Computer based inventory control systems.
UNIT III
Cost factor: The importance of costs, elements of costs, principles of cost determination and
accounting systems, production and inventory cost factors, other costs to the firm.
Economic quantities of manufacture or purchase: Lot size problems, finite production rates in
manufacturing, quantity discounts.
Uncertainty: Effects of uncertainty, demand and supply, safety stock, role of forecasting in
production and inventory control. uncertainty in production cycling
UNIT IV
Production planning: Scope of planning, types of production planning, demand analysis,
seasonal and non-seasonal demand. Planning procedures. Setting the production rate. Short term
and long term planning - make and buy decisions, product design and process selection,
manufacturing planning.
UNIT V
Production control: Control objectives, problems in production control, types of production and
production control systems, controlling production, routing, scheduling and dispatching.
Lay out of the physical system, design of a production planning and control systems. Application
of computers in production planning and control.
75
Text Book:
1. Production planning and inventory control - Magee and Boodman.
References:
1. Production control - John E Biegal.
2. Production forecasting, planning and control - EH Mac Niece.
3. Elements of production planning and control - Samuel Eilon.
4. Production Planning and Inventory Control – Seetharama L Narasimhan, Dennis W,
McLeavey, Peter J Billington.
5. Industrial Engineering and Management – O P Khanna.
76
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME604: CAD/CAM
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Overview of CAD systems: Fundamentals of CAD-Introduction –Types of systems, Input
devices, Output devices; CAD Software – Graphic terminal, Graphics standards, basic
definitions of Data structure, database, Data Base Management Systems, Database, working and
screen coordinate systems, modes of graphic operation, user interface, software modules,
modeling and viewing.
UNIT II
Geometric Modeling: Wire frame models - Types and Mathematical parametric representation
of analytic and synthetic curves; Surface models - Types and Mathematical parametric
representation of analytic and synthetic surfaces; Solid models – solid entities, solid
representation; fundamentals of solid modeling, Introduction to Boundary representation and
Constructive solid geometry.
UNIT III
Two and Three dimensional Graphics concepts: Geometric Transformations –
Transformations of geometric models, Mappings of geometric models, Inverse transformations
and mapping, projections of geometric models.
NC Part Programming: Introduction to NC part programming, methods- manual part
programming, computer assisted part programming, advantages and limitations of programming
methods. NC tooling and Automatic Tool Changers. NC, CNC & DNC machines.
UNIT IV
Introduction to Robotics: Types of robots, specifications and applications, advantages and
limitations.
Group technology and flexible manufacturing system: Part families, parts classification and
coding, production flow analysis, machine cell design, FMS workstations, Material handling and
storage system, Computer control system, planning the FMS, analysis methods for flexible
manufacturing system, Application & benefits of Group technology and FMS.
UNIT V
Computer integrated planning system: CIM, CAPP, MPS, MRP-I, MRP-II, Capacity
planning, shop floor control, Problems with conventional production system, Applications of
computers in manufacturing, Planning and control.
Text Book:
1. Automation, Production systems & Computer integrated manufacturing by M.P.Groover PHI
publications.
Reference:
1. CAD/CAM Principles and Integration by P.N.Rao, Tata McGraw hill publishers.
2. Computer Aided Design & Manufacturing by Sadhu Singh, Khanna Publishers.
77
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME 605: AUTOMOBILE ENGINEERING
Hours per week: 3 End Examination: 60 Marks
Credits: 3 Sessionals: 40 Marks
UNIT I
Introduction: Classification of vehicles - options of prime movers, transmission and
arrangements.
Engine: Engine classifications - number of strokes, cylinders, types of combustion chambers
for petrol and diesel engines, valves, valve arrangements and operating mechanisms, piston
- design basis, types, piston rings, firing order,fly wheel.
UNIT II
Fuel supply systems for petrol and diesel engines, fuel pumps - Mechanical and electrical
diaphragm pumps, air and fuel filters, carburetors, fuel injection systems for diesel and
petrol engines, electronic fuel injection, super chargers, mufflers.
UNIT III
Cooling system for I.C. engines:- Necessity, methods of cooling, air cooling, water cooling,
components of water cooling systems.
Lubrication systems:- Objective of lubrication, requirements of lubricant, types of lubricant,
various systems of engine lubrication.
Electrical systems:- Ignition system, distributor, electronic ignition, magneto, dynamo,
alternator, regulator, starting motor, introduction to various accessories, typical wiring diagram.
UNIT IV
Chassis systems: Introduction of chassis, classification, conventional construction, frameless
construction, introduction to vehicle dimensions.
Transmission systems: Introduction to single plate clutch, wet and dry type, clutch actuating
mechanisms, study of clutch components, fluid fly wheel.Gear box - Theory, four speed and
five speed sliding mesh, constant mesh and synchromesh type, selector mechanism,
automatic transmission, overdrive, transfer box four wheel drive, torque converter, propeller
shaft.
UNIT V Suspension and steering system: Suspension: Systems, springs, shock absorbers, axles - front
and rear, different methods of floating rear axle, front axle and wheel alignment, types of rims
and tyres. Steering mechanisms, types of brakes and brake actuation mechanisms.
Text Books:
1. Automobile Engineering, Vol.-1 & 2 by Kripal Singh, Standard publisher distributors
2. Automotive Mechanics by Joseph Heitner, East-West student edition
References:
1. Automobile Mechanics by Crouse. W.H. and Angling. D.L.
2. Automobile Electrical System by Judge, A.W.
3. Automobile engineering by K.K.Ramalingam, Scitech publications
78
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME611: PRODUCTION DRAWING LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. Representation of limits, fits, tolerances, surface roughness & Geometric tolerance on
production drawing as per IS 8000, IS 696
2. Part drawings and assembly drawings.
3. Location theory 3-2-1 principle, types of jigs and fixtures, production drawing of jigs and
fixtures
4. Stock strip layouts in sheet metal drawings, press tool, forging dies.
5. Production drawings of single point cutting tool, milling cutter, broaching tool and
adopters (CNC Tooling)
6. CAD packages like AutoCAD/CATIA can be used for drawing practice
Text Books:
1. Production Drawing by K.L.Narayana, New age publishers
2. Jigs & Fixtures by Joshi, Khanna Publishers
3. Press Tool Design by Joshi, Khanna Publishers
References:
1. Production Technology Hand Book- HMT,
2. Metal Cutting by Arsinov, MI.R. Publishing house.
3. NC & CAM by T.K. Kundra, P.N.Rao, N.K.Tewari, 2002, TMH
4. Tool Engineering & Design by G.R. Nagpal ,Khanna Publishers – 2002.
79
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME612: METROLOGY LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. Calibration of micrometer and dial gauge by using slip gauges.
2. Measurement of angle gauges by using bevel protractor and sine bar.
3. Measurement of taper angle of V-groove by using vernier height gauge.
4. Measurement of central distance between two holes by using vernier height gauge.
5. Gear metrology-to find module, addendum, dedendum, pitch circle diameter, tooth width,
pressure angle of a given spur gear.
6. To check roundness and concentricity of spigot
7. To check straightness of surface plate by using spirit level and autocollimeter.
8. Study of flatness of slip gauges by using monochromatic check light.
9. Tool maker‟s microscope-To study screw thread profile (Major dia, minor dia, pitch,
thread angle) and tool angles.
10. Measurement of Surface roughness by using Stylus method.
80
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME 613: INDUSTRIAL ENGINEERING LAB
Hours per week: 3 Continuous Evaluation: 100 Marks
Credits: 2
1. To draw two handed process charts for Bolt, Washer and nut assembly
2. To draw Multiple activity chart using an electric toaster.
3. To Conduct stop watch time study for the assembly of electric plug and determine
observed time, normal time and standard time.
4. To determine the cycle time using PMTS.
5. Time study using pin board apparatus
6. To conduct physiological test on bicycle ergometer and to identify the changes in heart
beat rate, oxygen consumption rate during working and recovery method
7. To conduct physiological test on bicycle tread mill and to identify the changes in heart
beat rate, oxygen consumption rate and energies expenditure during working and
recovery method
8. To show that the sample means from a normal universe follow a normal distribution.
9. To draw the control chart for fraction defective for a given lot of Plastic Balls.
10. To draw X & R Chart to determine the process capability for the measurement of smaller
diameter of a given set of stepped pins.
11. To draw C- Chart for number of defects.
12. To plot operating characteristic curves for a single sample attributes plan of a given lot of
plastic balls sand to compare the actual O.C curve with theoretical O.C curve
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Sixth Semester
EIRME613: PERSONALITY DEVELOPMENT
Hours per week: 3 Cont. Evaluation: NA
Credits: NA
81
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME701: FINITE ELEMENT ANALYSIS (Common to both Manufacturing and Thermal streams)
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Fundamental Concepts: Introduction, Historical background, Stresses and Equilibrium,
Boundary conditions, Strain-Displacement relations, Stress-Strain relations, Plane stress,
Plane strain problems, Temperature effects, Potential energy and Equilibrium. The Raleigh-
Ritz method, Hamilton's principle. Galerkin's method, Saint Venant‟s principle.
UNIT II
One-dimensional Problems: Introduction, Finite element modeling, coordinates and Shape
functions. The potential energy approach. The Galerkin approach, Assembly of the global
stiffness matrix- mass matrix and load vector, Treatment of boundary conditions, Quadratic
shape functions, Temperature effects.
Trusses: Introduction, Plane trusses, Three-dimensional trusses, Assembly of global stiffness
matrix for the Banded and Skyline solutions.
UNIT III
Two-dimensional Problems Using Constant Strain Triangles: Introduction, Finite element
modeling, Constant strain triangle, in plane and Bending, problem modeling and boundary
conditions.
Axisymmetric Solids Subjected to Axisymmetric Loading: Introduction, Axisymmetric
formulation, Finite element modeling, Triangular element, Problem modeling and boundary
conditions.
UNIT IV
Two-dimensional Isoparametric Elements and Numerical Integration: Introduction, The
four-node quadrilateral, Numerical integration, Higher-order elements.
Beams and Frames: Introduction, Finite element formulation, Load vector, Boundary
considerations, Shear force and bending moment, Beams on elastic supports, Plane frames.
UNIT V
Dynamic considerations: Introduction, formulation, element mass matrices, evaluation of Eigen
values and Eigen vectors.
Introduction to FEA packages: ANSYS, MS –NASTRAN, NISA-II
82
Text Book:
1. Introduction to Finite Elements in Engineering, by Tirupathi R. Chandrupatla, Ashok
D.Belegundu. Third edition, Pearson education.
References:
1. Introduction to Finite Element Method, by Abel & Desai, CBS Publishers.
2. Finite Element Method, by O.C. Zienkiewicz., McGraw-Hills Publishers
3. Concepts and Applications of Finite Element Analysis, by Robert D. Cook., John Wiley &
Sons.
4. Finite element method in engineering by S.S.Rao., Butterworth-Heinemann publishers
5. Finite element method by JN Reddy, Mc/Graw-Hil
6. Finite element method by P.Seshu. PHI Learning Pvt. Ltd.
83
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME702M: ROBOTICS AND ROBOT APPLICATIONS Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Introduction and Robot Kinematics: Definition need and scope of Industrial robots – Robot
anatomy – Work volume – Precision movement – End effectors – Sensors.
Robot Kinematics – Direct and inverse kinematics – Robot trajectories – Control of robot
manipulators – Robot dynamics – Methods for orientation and location of objects.
UNIT II
Robot Drives and Control: Controlling the Robot motion – Position and velocity sensing
devices – Design of drive systems – Hydraulic and Pneumatic drives – Linear and rotary
actuators and control valves – Electro hydraulic servo valves, electric drives – Motors –
Designing of end effectors – Vacuum, magnetic and air operated grippers.
UNIT III
Robot sensors: Transducers and Sensors – Sensors in Robot – Tactile sensor – Proximity and
range sensors – Sensing joint forces – Robotic vision system – Image Gribbing – Image
processing and analysis – Image segmentation – Pattern recognition – Training of vision system.
UNIT IV
Robot Cell Design and Application: Robot work cell design and control – Safety in Robotics –
Robot cell layouts – Multiple Robots and machine interference – Robot cycle time analysis.
Industrial application of robots.
UNIT V
Robot Programming, Artificial Intelligence and Expert Systems :
Methods of Robot Programming – Characteristics of task level languages lead through
programming methods – Motion interpolation. Artificial intelligence – Basics – Goals of
artificial intelligence – AI techniques – problem representation in AI – Problem reduction and
solution techniques - Application of AI and KBES in Robots.
Text Book:
1. Robotics Technology and Flexible Automation by S.R. Deb, Sankha DebTata McGraw
Hill Company Ltd, 2009.
References:
1. K.S.Fu, R.C. Gonzalez and C.S.G. Lee, “Robotics Control, Sensing, Vision and Intelligence”,
Mc Graw Hill, 1987
2. Yoram Koren, “Robotics for Engineers” Mc Graw-Hill, 1987.
3. Kozyrey, Yu. “Industrial Robots”, MIR Publishers Moscow, 1985.
4. Richard. D, Klafter, Thomas, A, Chmielewski, Michael Negin, “Robotics Engineering – An
Integrated Approach”, Prentice-Hall of India Pvt. Ltd., 1984.
5. Mikell, P. Groover, Mitchell Weis, Roger, N. Nagel, Nicholas G. Odrey,” Industrial Robotics
Technology, Programming and Applications”, Mc Graw-Hill, Int. 1986.
84
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME702T: COMPUTATIONAL FLUID DYNAMICS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Finite difference methods: Taylor‟s series – FDE formulation for 1D and 2D steady state heat
transfer problems – Cartesian, cylindrical and spherical co-ordinate systems – boundary
conditions – Un steady state heat conduction – Errors associated with FDE - Explicit Method –
Stability criteria – Implicit Method – Crank Nickolson method – 2-D FDE formulation – ADI –
ADE
UNIT II
Finite Volume Method: Formation of Basic rules for control volume approach using 1D steady
heat conduction equation – Interface Thermal Conductivity - Extension of General Nodal
Equation to 2D and 3D Steady heat conduction and unsteady heat conduction
UNIT III
Incompressible Fluid Flow: Governing Equations, Stream Function - Vorticity method,
Determination of pressure for viscous flow, SIMPLE Procedure of Patankar and Spalding,
Computation of Boundary layer flow, Finite difference approach
UNIT IV
Convection Heat Transfer: Solution of one dimensional and two dimensional steady/unsteady
convection – Diffusion, Discretization Schemes and their assessment Treatment of Boundary
Conditions- Diffusion problems, Convection problems, Convection-diffusion problems
UNIT V
Turbulence Models: Algebraic Models – Turbulence models - Zero-Equation, One-Equation,
Two-Equation & Stress-Equation Turbulent Models- K - ε Models, Standard and High and Low
Reynolds number models.
Text Books:
1. Anderson, D. A, Tannehill, J. C., and R. H. Pletcher, R. H., Computational Fluid Mechanics
and Heat Transfer, Second Edition, Taylor & Francis, 1995.
2. Versteeg, H. K. and W. Malalasekera, W., An Introduction to Computational Fluid
Dynamics: The Finite Volume Method, Addison Wesley – Longman, 1995
References:
1. Chow, C.Y, Introduction to Computational Fluid Dynamics, John Wiley, 1979.
2. Muralidhar, K., and Sundararajan, T., “Computational Fluid Flow and Heat Transfer”,
Narosa Publishing House, New Delhi, 1995
3. Hirsch, A.A., Introduction to Computational Fluid Dynamics, McGraw Hill, 1989.
4. Patankar, S.V., Numerical heat transfer and fluid flow, Hemispher Publishing Corporation,
1992
5. Bose, T.K., Computation Fluid Dynamics, Wiley Eastern Ltd., 1988.
85
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME703M: FLEXIBLE MANUFACTURING SYSTEMS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Introduction: The economic justification of FMS, The basic components of FMS and their
integration in the data processing system, The concept of the 'total system'. The FMS relational:
Economic and technological justification for FMS Management decisions during FMS project
planning, design and implementation: Designing the FMS, Data processing design, FMS project
and software documentation.
UNIT II Design and Planning of FMS: the role of associated technologies such as GT, JIT and
simulation Installation, Operation and evaluation Scheduling problems. Control aspects of
FMSDNC of machine tools, cutting tools, robots, quality control and inventories.
UNIT III
Distributed processing in FMS: Introduction to database management systems (DBMS) and
their application in CAD/CAM and FMS, Distributed systems in FMS. Distributed tool data
bases in FMS: The distributed tool data structure with a general purpose tool description facility,
Implementation of the FMS tool data base, Application possibilities of the FMS tool data base.
UNIT IV
FMS database for clamping devices and fixtures: The FMS clamping device and fixture data
base, The analysis and calculation of pallet alignment and work mounting errors, Mating surface
description methods for automated design and robotised assembly, Application of industrial
robots in FMS, The application of automated guided vehicle (AGV) systems.
UNIT V
Inspection and Cleaning stations: Personnel and infrastructural aspects Flexible machining
cells and islands Flexible assembly Systems; structure, control and applications FMS in
action: Typical case studies. Future prospects.
Text Books:
1. The Design and Operations of FMS by Dr. Paul Ranky, IFS (Publications) Ltd., UK,
1983.
2. Flexible Manufacturing Systems in Practice by Joseph Talavage and Roger G. Hannam,
Marcel Dekker Inc., New York, 1988
3. Robotics Technology and Flexible Automation by S.R. Deb, Sankha DebTata McGraw
Hill Company Ltd, 2009.
86
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME703T: ADVANCED FLUID MECHANICS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Inviscid Flows: Complex potentials for simple flows, uniform flow, source, sink and vortex,
combination of simple flows, Rankine half body, Rankine oval, doublet, flow past cylinder,
calculation of lift, Magnus effect; Conformal transformation, transformations of the circle,
Jowkowski transformation, flow over an ellipse, flow past a flat plate, aerofoil, lift calculation,
Kutta condition, Stokes stream function for axi-symmetric flows, Irrotational flow equations,
flow past a stream-lined body.
UNIT II
Viscous flow : Exact solution of incompressible Navier-Stokes equations – Couette flow, flow
between rotating cylinders, Stokes problems, stagnation point flow, flow near a rotating disk,
fully developed flow through ducts; Low Reynolds number flows, use of vorticity and stream
function, creeping flow past a sphere, hydrodynamic theory of lubrication
UNIT III
Concept of Turbulence: Concept of linearized stability of parallel viscous flow, transition to
turbulent flow, Reynolds equation for turbulent flow, Reynolds stresses, Prandtl‟s mixing length
theory, velocity profile, turbulent flow in pipes, eddy viscosity. Free turbulence – jets, wakes and
mixing layer.
UNIT IV
Boundary layer flow: Flows around a body – Forces acting on a body- The drag of a body-drag
coefficient-drag for cylinder- sphere-flat plate –friction torque acting on revolving discs-The lift
of a body - Development of lift –wing-Cavitation- Boundary Layers in Rotating Flows
UNIT V
Non-Newtonian Fluid flow: Non-Newtonian Fluids and Generalized Newtonian- Rheological
Classifications- Generalized Newtonian Fluid Flows- Simple Shear Flow- Shear free Flow-
Oscillatory Rheometric Flow- Visco-metric Flow in Rheometry- Visco-elastic Fluids and Flow -
Linear and Nonlinear Visco-elastic Models- Visco-elastic Models to Standard Flow and
Application to Some Engineering Flow Problems-.
87
Text Books:
1. Munson, B.R., Young, D.F. and Okiisi, T.H., Fundamentals of Fluid Mechanics,John Wiley
and Sons Inc., NewYork, 1990
2. Fundamentals of Fluid Mechanics, Schlitching
3. Advanced Fluid Mechanics by Muralidhar & Biswas
References:
1. Introduction to Fluid Mechanics, Shaughnessy, Oxford University Press
2. Viscous Fluid Flow by F.M.White
3. A.H. Shapin, „The dynamics and thermodynamics of compressible fluid flow‟, Vol. I and II,
The Ronald Press Co., 1955
88
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME711: CAD/CAM LAB
Hours per week: 3 Continuous evaluation :100 Marks
Credits: 2
1. Introduction to Modeling packages - ProEngineer, Ideas, Catia, Uni Graphics, Solid
Works.
2. 2D-Modeling of simple objects
3. 3D-Modeling of simple objects
4. Preparation of manual part programme for turning, drilling and milling
5. To Generate NC programme using Master CAM / Edge CAM simulation software for a
turning Job using Lathe Version.
a. Step turning, taper turning, drilling
b. Thread cutting, grooving,
6. To Generate NC programme using Master CAM / Edge CAM simulation software for a
3-axis machining Milling Version.
a. Face milling, pocketing , drilling, contouring
b. Gear cutting.
7. Machining of one job on CNC Lathe.
8. Machining of one job on CNC Drilling.
89
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME 712: HEAT AND MASS TRANSFER LAB
Hours per week: 3 Continuous evaluation: 100 Marks
Credits: 2
1. Determine the Temperature Distribution and overall thermal conductance across the
width of composite wall.
2. Determine the thermal conductivity of a metal rod.
3. Determine the heat transfer coefficient for a vertical cylinder in natural convection
4. Determine the heat transfer coefficient in forced convection of air in a horizontal tube.
5. Determine the emissivity of the test plate surface.
6. Determine the efficiency of a pin fin in natural convection.
7. Determine the efficiency of a pin fin in forced convection.
8. Determine the effectiveness of a parallel flow heat exchanger.
9. Determine the effectiveness of a counter flow heat exchanger.
10. Determine the heat transfer coefficients on Film and Drop wise condensation
apparatus.
11. Determine the heat transfer rate and effectiveness of computer-controlled heat
exchanger in parallel and counter flow.
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Seventh Semester
EIRME 713: INTERNSHIP
Duration: 3 months Continuous evaluation: 100 Marks
Credits: 8
90
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME801M: METAL FORMING TECHNIQUES
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Introduction of metal forming as a manufacturing process, and its relation with other processes,
Metal Forming from systems point of view, Advantages of metal forming as a manufacturing
process, Classifications of metal forming processes, Forming equipments, Presses (mechanical,
hydraulic).
UNIT II
Theoretical analysis (theory of plasticity): Stress-strain relationship, Strain hardening, Material
incompressibility, Work of plastic deformation, Work hardening, Yield criteria, Flow rule, Yield
criterion and flow rule for Anisotropic material, Initiation and extent of plastic flow
(microstructural point of view). Formability of sheet, Formability tests, Forming limit diagrams.
UNIT III
Analysis of forming processes, Slab analysis : Open-die forging, Plate drawing, Flat rolling,
Deep drawing of sheet, Other methods of analysis like FEM, upper bound, slip line field. Process
simulation for deep drawing and numerical approaches.
UNIT IV
Overview of various metal forming operations: Forging; open-die forging, closed-die forging,
coining, nosing, upsetting, heading, extrusion and tooling, Rod, wire and tube drawing, Rolling;
flat rolling, shape rolling and tooling.
UNIT V
Sheet forming: blanking, piercing, press bending, deep drawing, stretch forming, spinning.
Hydroforming, rubber-pad forming, explosive forming, Hot and cold pressing (HIP, CIP), High
Energy Rate Forming (HERF), electroforming.
Text Book:
1. Hosford W.F and Caddell, R.M,, “Metal Forming Mechanics and Metallurgy”, Prentice
Hall,1983.
References:
1. Narayanasamy R., “Theory of Plasticity”, Ahuja Publications, 2000.
2. Scrope Kalpakjian,, “Manufacturing processes for Engineering Materials”, Addision Wesley,
1997.
91
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME801T: ADVANCED HEAT & MASS TRANSFER
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Conduction Heat Transfer: One dimensional steady state heat conduction with heat source -
extended surface heat transfer- Fins of non uniform cross section- unsteady state conduction with
moving source.
Finite Difference methods for Conduction: 1D & 2D steady state and simple transient heat
conduction problems – implicit and explicit methods.
UNIT II
Turbulent Forced Convective Heat Transfer: Von- Karman and Van Driest expressions for
diffusivity - mixing length concept, friction factor ,turbulence model – k -Є model - analogy
between heat and momentum transfer– Reynolds, Colburn, Prandtl analogies - turbulent flow in
a tube-,Shear velocity and heat transfer for various boundary conditions. Heat transfer at high
velocities for constant and variable fluid property.
UNIT III
Radiation Heat Transfer: Heat radiation through absorbing and transmitting media. Combined
mode of heat transfer -Radiation with conduction and convection surfaces. Gas radiation –
radiative properties of gases, radiation from gases.
UNIT IV
Heat Exchangers: Heat exchangers with phase change - Heat transfer coefficient during phase
change on tube bank, Simplified relations for boiling heat transfer with water - transpiration
cooling - ablation, classification, construction and applications of heat pipe-compact heat
exchangers.
UNIT V
Mass Transfer: Diffusion of gases, Liquids- Mass transfer coefficient. Theories of Mass
Transfer, Vaporization of droplets, combined heat and mass transfer problems, Heat Transfer
Correlations in I.C. Engines.
Text Books:
1. Heat Transfer by J.P. Holman, Tata McGraw Hill Publication, 9th ed. 2002.
2. Heat and mass Transfer by N. Ozisik
3. Incropera F.P. and DeWitt. D.P., Fundamentals of Heat & Mass Transfer, John
4. Wiley & Sons, 2002
References:
1. Nag.P.K, Heat Transfer, Tata McGraw-Hill, 2002
2. Ghoshdastidar. P.S., Heat Transfer, Oxford University Press, 2004
3. Heat pipe theory application Springer link Publication, by S. W. Chi, 1998
92
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME802M: ADVANCED MANUFACTURING PROCESSES
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Adaptive Control: Definition of Adaptive Control, Classification of Adaptive Control, Adaptive
Control Constraint, Adaptive Optimization , Adaptive Controlled optimization for Machining
Process.
UNIT II
Lean, Agile and JIT Manufacturing: Introduction to Lean manufacturing, types of wastes in
lean manufacturing, comparison lean and Agile manufacturing, Comparison of lean and agile.
JIT Approach, Introduction, Definition, Elements of JIT, How JIT works, Effects of JIT
production, Plant layout for JIT, Product Design for JIT, Steps in implementation of JIT,
Benefits of JIT.
UNIT III
Rapid Prototyping: Definition- basic steps in rapid prototyping- various techniques in Rapid
prototyping, applications of rapid prototyping. Nano Manufacturing: Introduction, Definition,
history of nano technology, approaches for synthesis of nano materials, Characteristics of Nano
particles, applications of Nano technology
UNIT IV
Production Support Machines and Systems: Introduction ,working principle of various
production systems like Automatic Conveyor systems, Automated Guided Vehicles, Rail Guided
Vehicles, Industrial Robots.
UNIT V
Manufacturing system Simulation: Introduction, Some definitions for simulation, types of
simulation, need for simulation, Simulation structure and elements of simulation, simulation
methodology, cycle diagrams.
Text Books:
1. Manufacturing Engineering and Technology by Serope Kalpakjian, Steven & Schmid, 4th
edition, Pearson Education Publications.
2. Computer aided design and manufacturing by Betworth, Tata Mc. Grawhill
References:
1. Computer Integrated Manufacturing by Dr. Sadhu Singh, Khanna Publishers.
2. CAD/CAM principles and applications by PN.RAO-TMH
93
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME802T: DESIGN OF THERMAL EQUIPMENTS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Mathematical Modelling: Equation Fitting , Nomography , Empirical Equation , Regression
Analysis , Different Modes of Mathematical Models , Selection, Computer Programmes for
Models.
Design Aspects: Heat transfer and pressure loss – flow configuration – effect of baffles – effect
of deviations from ideality
UNIT II
Modelling Thermal Equipments: Modelling Heat Exchangers , Evaporators , Condensers ,
Simulation Studies , Information Flow Diagram, Solution Procedures.
UNIT III
Compact and Plate Heat Exchangers: Types – merits and demerits – Heat transfer and
pressure loss – flow configuration – effect of parameters and deviations from ideality – design,
rating and simulation of compact heat exchangers, plate heat Exchangers – performance
influencing parameters - limitations.
UNIT IV
Condensers and Cooling Towers: Direct contact heat transfer – Design of surface and
evaporative condensers – cooling tower – performance Characteristics. Boiler furnace and super
heaters design: principles of boiler design, codes for mechanical design of he, fouling of he,
testing, evaluation and maintenance of HE
UNIT V
Heat Transfer Enhancement: Augmentation techniques – active techniques such as providing
suction, vibration, rotation etc. And passive techniques such as providing fins, turbulent
promoters, rough surfaces etc. Design of heat exchangers for automotive, refrigeration,
cryogenic and chemical process plants.
Text Books:
1. Arthur. P Frass, Heat Exchanger Design, John Wiley & Sons, 1988.
2. Taborek.T, Hewitt.G.F and Afgan.N, Heat Exchangers, Theory and Practice, McGraw-Hill
Book Co. 1980
3. Sadik Kakac and Hongtan Liu, Heat Exchangers Selection, Rating and Thermal Design, CRC
Press, 2002
4. Stoecker W. F., Design of Thermal Systems , McGraw Hill Edition , 1989
94
References:
1. E. Hesselgreaves, Compact Heat Exchangers, Elsevier, 2001.
2. R. K. Shah & D. P. Sekulic, Fundamentals of Heat Exchanger Design, John Wiley, 2003.
3. E. M. Smith, Advances in Thermal Design of Heat Exchangers, John Wiley, 2005
4. David Gunn, Robert Horton, Industrial Boilers - Longman Scientific & Technical Publ, 1986.
95
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME803M: CNC MACHINES & PART PROGRAMMING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Introduction: NC, CNC, DNC, Programmed Automations, Machine Control Unit, Part program,
NC tooling. NC Machine tools: Nomenclature of NC machine axes, Types of NC machine tools,
Machining centers, Automatic tool changers(ATC), Turning centers.
UNIT II
Machine Control Unit & Tooling: Functions of MCU, NC actuation systems(NCAS), Part
program to command signal, MCU Organization, Computerized Numerical Control, Transducers
for NC machine tools, Tooling for NC machining centers and NC turning machines, Tool
presetting.
UNIT III
Manual Part Programming: Part program instruction formats, information codes: preparatory
function, miscellaneous functions, tool code and tool length offset, interpolations, canned cycles.
Manual part programming for milling operations, turning operations, parametric sub routines.
UNIT IV
Computer aided part programming: NC languages: APT, NELAPT, EXAPT, GNC, VNC, pre-
processor, post- processor.
UNIT V
APT programming: APT language structure, APT geometry: Definition of point, time, vector,
circle, plane, patterns and matrices. APT motion commands: set-up commands, point-to-point
motion commands, continuous path motion commands. Post-processor commands, complication
and control commands. Macro sub routines. Part programming preparation for typical examples.
Text Books:
1. Automation, Production systems & Computer integrated manufacturing" by
M.P.Groover, PHI Publications,
2. CAD/CAM principles & applications by P. N. Rao, Ist edition, Tata McGraw Hill
publications.
References:
1. Manufacturing systems Engineering by Katsundo Hitomi , Second Edition, Viva Low
Priced Student Edition
2. Numerical control of Machines Tools by Yoram Koren and Joseph BenUri, Khanna
publications.
3. Manufacturing Engineering and Technology by Serope Kalpakjian, Steven & Schmid,
4th edition-Pearson Education Publications
96
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME803T: MODERN ENERGY SYSTEMS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Wind Turbine: Structure - Statistics - Measurements and Data Presentation - Wind Turbine
Aerodynamics -Momentum Theories - Basics Aerodynamics - Airfoils and their Characteristics-
HAWT–Blade Element Theory- Prandtl's Lifting Line Theory (prescribed wake analysis) –
VAWT Aerodynamics - Wind Turbine Loads - Aerodynamic Loads in Steady Operation – Wind
Turbulence - Yawed Operation and Tower Shadow.
UNIT II
Wind Energy Conversion System (WECS):Siting - Rotor Selection - Annual Energy Output -
Horizontal Axis Wind Turbine (HAWT) Vertical Axis Wind Turbine - Rotor Design
Considerations - Number of Blades - Blade Profile -2/3 Blades and Teetering - Coning -
Upwind/Downwind - Power Regulation - Yaw System -Tower - Synchronous and Asynchronous
Generators and Loads – Integration of Wind Energy Converters to Electrical Networks -
Inverters - Testing of WECS - WECS Control System - Requirements and Strategies‟ -
Miscellaneous Topics - Noise etc - Other Applications.
UNIT III
Tidal & Otec Energy Systems: power generation schemes-Wave Energy-Introduction-basic
theory-wave power devices- Open and Closed OTEC cycles-biophotolysis-Ocean Currents-
Salinity Gradient Devices-Environmental Aspects
UNIT IV
Hydrogen: Hydrogen – Properties –generation-Storage and handling, performance and safety
aspects
UNIT V
Geothermal & Biomass Energy: Geothermal energy: Origin and types of geothermal energy
and utilization.- Biomass direct combustion – Biomass gasifier – Biogas plant – Ethanol
production – Biodiesel – Cogeneration – Biomass applications
Text Books:
1. L.L.Freris, Wind Energy Conversion Systems, Prentice Hall, 1990.
2. D.A.Spera, Wind Turbine Technology: Fundamental concepts of Wind Turbine
Engineering,ASME Press
3. D. Y. Goswami, F. Kreith, Energy Conversion- CRC Press, 2007
4. G.D. Rai, Non Conventional Energy Sources, Khanna Publishers, NewDelhi, 1999
5. M. Dayal, "Energy today & tomorrow", I & B Horishr India, 1982
97
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME 804A: DATA BASE MANAGEMENT SYSTEMS
(Common with EURME852)
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I Introduction to DBMS, Overview, File system vs DBMS, Advantages of DBMS, Storage data,
queries, Transaction Management, DBMS Structure
UNIT II
E-R model Entities, Attributes and Entity sets, Relationship and Relationship sets, Features of
ER model, Conceptual database design with ER model.
UNIT III Relational model – integrity constraints over relations and enforcement, Querying relation data,
Logical database design, views, destroying/altering tables and views. Relational algebra and
calculus
UNIT IV
SQL – Basic SQL, Query, union, interest, except, Nested Queries, Aggregated Operation, Null
values, Embedded SQL, cursors, ODBC and JDBC, Triggers and Active database, designing
active databases
UNIT V
Transaction management, concurrency control & crash recovery – Transaction concept,
transactions and schedules, concurrent execution of transactions, lock – based concurrency
control, crash recovery. Case Study: Oracle0i (SQL, PL/SQL & Triggers)
Text Books:
1. Database Management Systems – Raghu Ramakrishnan and Johannes Gehrke McGraw-Hill
2. Data System Concepts – H.F.Korth and A.Silberschatz McGraw-Hill
Reference: 1. Fundamentals of Database System – R.El. Masri and S.B.Navathe
98
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME804B: ARTIFICIAL INTELLIGENCE IN MANUFACTURING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Artificial Intelligence - Definition Components - Scope - Application Areas; Goals of
artificial intelligence – AI techniques – problem representation in AI – Problem reduction and
solution techniques
UNIT II
KnowledgeBased Systems (Expert Systems) - Definition - Justification - Structure –
Characterization
UNIT II
Knowledge Sources – Expert - Knowledge Acquisition- Knowledge Representation -
Knowledge Base - Inference Strategies - Forward and Backward Chaining; Expert System
Languages - ES Building Tools or Shells; Typical examples of shells.
UNIT III
Expert Systems Software for Manufacturing applications in CAD, CAPP, MRP, Adaptive
Control, Robotics, Process Control, Fault Diagnosis, Failure Analysis; Process Selection,
GT etc. Linking Expert Systems to other software such as DBMS, MIS, MDB; Process
Control and Office Automation.
UNIT V
Case studies of typical applications in Tool selection, Process selection, Part classification,
Inventory control, Process Planning etc.
Text Books:
1. Russell, Artificial Intelligence: A Modern Approach, 2/E, Pearson Education Inc., 2009.
2. M. Tim Jones, Artificial Intelligence: A Systems Approach, Jones and Bartlett Publishers,
Canada, 2009.
3. Robotics Technology and Flexible Automation by Deb, S.R, Tata Mc Graw-Hill, 1994
99
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME 804C: WEB TECHNOLOGY
(Common with EURME863)
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Introduction to Web Technology: Internet, WWW, Web Browsers, Web Servers, URL.
UNIT II
Introduction to HTML & DHTML: Syntax, Forms, Cascade Style Sheets.
UNIT III
The Basic of java Script, Perl, Primitives, Operator and Expression. Dynamic Document with
Java Script.
UNIT IV
Introduction to Java Servelets Programming., Introduction to Applet Programming.
UNIT V
Structure of Web Application, Deploying Web Application.
Text Books: 1. Programming the World Wide Web by Robert W Sebesta
2. Professional Java Servelets 2.3 by John Bell Wrox Publical
3. Beginners PHP, Apache, MY Sql, Web Development, by Michael Glass Wrox.
100
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME 804D: DATA STRUCTURES
(Common with EURME8518)
Hours per week: 4 End Examination: 60 Marks
Credits : 4 Sessionals: 40 Marks
UNIT I
Introduction to data types, Data structures and abstract data type (ADT), Complexity analysis of
algorithms; List, Stack, Queue and Recursion.
UNIT II
Tree – Terminology, tree as ADT and data structure, Binary tree, BST, AVL trees, B Trees, Bit
vector and link list implementation of a set, sets with MERGE and FIND operation,
Implementation of dictionary, hash table, priority queue.
UNIT III
Graph – Definition and representation, directed graph, single source shortest path, all pair
shortest path, directed acyclic graph (DAG), minimum cost spanning tree, traversal, articulation
point and bi connected components.
UNIT IV
Sorting and searching – Bubble sort, Insertion sort, Quick sort, merge sort, heap sort, binary
search.
UNIT V: Issues in memory management, storage allocation, garbage collection, compaction.
Text Books:
1. Fundamentals of Data Structures by E. Horowitz, S. Sahni, Galgotia Publishers.
2. Data structures using C/C++ by Tanenbaum, A.S., Langsam, Y and Augenstein, M..J.,
PHI
References:
1. Data Structures by V. Aho, J.D. Ullman, Addision Wesley.
2. The art of Computer Programming by D. E. Knuth, Narosa Publishers. (Vol.1)
3. Algorithms , Data Structures, Programs by N. Wirth, Prentice Hall India
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Eighth Semester
EIRME811: PROJECT -1
Hours per week: 8 End Examination: 50 Marks
Credits: 8 Sessionals:50 Marks
101
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME901M: ADVANCED OPTIMIZATION TECHNIQUES
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Geometric programming (G.P): Solution of an unconstrained geometric programming,
differential calculus method and arithmetic method. Primal dual relationship and sufficiency
conditions. Solution of a constrained geometric programming problem (G.P.P), Complementary
Geometric Programming.
UNIT II
Dynamic programming(D.P): Multistage decision processes. Concepts of sub optimisation,
computational procedure in dynamic programming calculus method and tabular methods. Linear
programming as a case of D.P and Continuous D.P.
UNIT III
Integer programming(I.P): Graphical representation. Gomory's cutting plane method. Bala's
algorithm for zero-one programming problem. Branch-and-bound method. Sequential linear
discrete programming, Generalized penalty function method
UNIT IV
Stochastic Programming (S.P): Basic Concepts of Probability Theory, Stochastic linear
programming
UNIT V
Unconventional optimization techniques: Multi-objective optimization - Lexicographic
method, Goal programming method, Genetic algorithms, Simulated Annealing, Neural Networks
based Optimization.
Text Book: 1. Engineering Optimization - Theory and Practice by Rao, S.S., New Age International (P) Ltd.
Publishers.
References:
1. Operations Research- Principles and Practice, Ravindran, Phillips and Solberg, John Wiely
2. Introduction to Operations Research, Hiller and Lieberman, Mc Graw Hill
3. Goal Programming and Extensions by James P. Ignizio, Lexigton Books.
4. Genetic Algorithms - In Search, Optimization and Machine Learning by David E. Goldberg,
Addison-Wesley Longman (Singapore) Pvt. Ltd
102
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME901T: ENERGY CONSERVATION AND MANAGEMNET
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Introduction: Energy Scenario - Principles and Imperatives of Energy Conservation - Energy
Consumption, Pattern – Resource Availability - Role of Energy Managers in Industries.
UNIT II
Thermal Energy Auditing: Energy Audit-Purpose, Methodology with respect to process
Industries - Power plants, Boilers etc., - Characteristic method Employed in Certain Energy
Intensive Industries - Various Energy Conservation Measures in Steam System - Losses in
Boiler, Methodology of Upgrading Boiler Performance Energy conservation in pumps, Fans &
Compressors, Air conditioning and Refrigeration systems, Steam Traps- Types, Function,
Necessity
UNIT III
Instruments For Energy Auditing: Instrument characteristics – sensitivity, readability,
accuracy, precision, hysteresis, error and calibration. Measurement of flow, velocity, pressure,
temperature, speed, Lux, power and humidity. Analysis of stack, water quality, power and fuel
quality.
UNIT IV
Energy Management: Principles of Energy Management – Managerial Organization –
Functional Areas for Manufacturing Industry- Process Industry-Commerce- Government, Role
of Energy Manager in each of these organization, Initiating, Organizing and Managing Energy
Management Programs
UNIT V
Energy Economics: Importance of Energy Management, Energy Economics - Discount Rate,
Payback Period, Internal Rate of Return, Life Cycle Costing
Text Books:
1. Smith, CB Energy Management Principles, Pergamon Press, NewYork, 1981
2. Hamies, Energy Auditing and Conservation; Methods Measurements, Management and Case
study, Hemisphere, Washington, 1980
References:
1. Trivedi, PR, Jolka KR, Energy Management, Commonwealth Publication, NewDelhi,1997
2. V. Kadambi, and M. Prasad, Introduction to energy conversion turbo machinery: Energy
conversion cycle- Wiley Eastern, New Delhi, 1974,
3. R. Gold Stick and A. Thumann, Principles of Waste Heat Recovery, PHI, 1986.
4. Write, Larry C, Industrial Energy Management and Utilization, Hemisphere Publishers,
Washington, 1988
103
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME902M: COMPUTER AIDED INSPECTION
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Introduction: Computer aided testing (CAT) and computer aided inspection (CAI), computer
aided quality control ( CAQC), on-line inspection and quality control, technology of automation
Gauging, automatic inspection machines, in-process gauging,
UNIT II
Co-Ordinate Measuring Machines: Basic Types of Measuring Machines, probe types,
operating modes, programming software's, accessories, measurement and inspection capabilities,
flexible inspection systems, inspection problems.
UNIT III
Machine Vision: Functions of machine vision system, evaluating the performance of machine
vision system, machine vision applications.
UNIT IV
Scanning Laser Beam Devices: Laser interferometer, laser, alignment devices, X-ray optics,
CCD (Charge-coupled Devices) Array, ultrasonic system.
Proximity Sensing: Photoelectric Transducers, Image processing for vision sensor,
3-dimensional object recognition.
UNIT V
Machine Tool Sensing: Part measurement, Tool wear, Axial, motion, Sequence of functions,
tool Identification. Computer aided surface roughness measuring systems, High accuracy profile
measuring systems.
Text Book:
1. Machine Vision- Nello Zueh and Richard K.Miller prentice hall,1987.
References:
1. Robot Sensors -Pugh, IFS Publication, 1986
2. Transducers and Interfacing -Bannister and Whitehead~ Von Nostrand. 1986
3. Computer Control of Manufacturing Systems -Koren, McGraw Hill, 1983
104
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME902T: HEATING, VENTILATION AND AIR CONDITIONING
&
CRYOGENICS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT-I
Psychometric Air Conditioning Processes, Dehumidification Processes, Comfort Air
Conditioning, Parameters Affecting Comfort Conditions, Cooling Load Calculations, Design Of
Air Delivery System To Hospital, Auditorium, Hotels Etc., Noise And Vibration Control In Air
Conditioning Hall.
UNIT II
Air Conditioning Equipments: Spray systems, chilled water and DE Coils, absorption and
adsorption systems, Air filtration, ducts, Design and constructional details of Unitary air
conditioning equipment.
UNIT III
Air Conditioning Component Selection (Component Matching), Designing Air Ducts, Window
Air Conditioner / Split Air Conditioner Performance Testing, Energy calculations- Degree-Day
procedure, Bin Method, Comprehensive Simulation methods method, Flow- Pump - and piping
Design.
UNIT-IV
Cryogenic Systems: Introduction: Insight on Cryogenics, Properties of Cryogenic fluids,
Material properties at Cryogenic Temperatures. Applications of Cryogenics in Space Programs,
Superconductivity, Cryo Metallurgy, Medical applications.
UNIT-V
Liquefaction Cycles: Carnot Liquefaction Cycle, F.O.M. and Yield of Liquefaction Cycles.
Inversion Curve - Joule Thomson Effect. Linde Hampson Cycle, Precooled Linde Hampson
Cycle, Claude‟s Cycle Dual Cycle, Ortho-Para hydrogen conversion, Eollins cycle, Simpson
cycle, Critical Components in Liquefaction Systems.
105
Text Books:
1. W.F Stocker. and J.W. Jones, „Refrigeration and Air-conditioning Data‟, McGraw Hill, 1985.
2. Herald Weinstock, Cryogenic Technology, 1969.
3. Robert W. Vance, Cryogenic Technology, Johnwiley & Sons, Inc., New York,London
References:
1. Klaus D. Timmerhaus and Thomas M. Flynn, Cryogenic Process Engineering, Plenum Press,
New York, 1989.
2. Randall F. Barron, Cryogenic Systems, McGraw-Hill, 1985.
3. Scott R.B., Cryogenic Engineering, Van Nostrand and Co., 1962.
4. W.F. Stoecker, and J.W. Jones, Refrigeration and Air Conditioning, II Ed, Tata McGraw
Hill, New Delhi 1982
5. W.R Haines and C.L Wilson, HVAC Systems Design Handbook, McGrawHill, 2nd Ed.,
New Delhi, 1994
106
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME903MA: RAPID PROTOTYPING AND VIRTUAL PROTOTYPING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Introduction : Need for time compression in product development, Product development –
conceptual design – development – detail design – prototype – tooling. Classification of RP
systems, Stereo lithography systems – Principle – process parameters – process details – machine
details, Applications.
UNIT II
Direct Metal Laser Sintering (DMLS) system: Principle – process parameters – process details
– machine details, Applications. Fusion Deposition Modeling – Principle – process parameters –
process details – machine details, Applications. Laminated Object Manufacturing – Principle –
process parameters – process details – machine details, Applications.
UNIT III
Solid Ground Curing: Principle – process parameters – process details – machine details,
Applications. 3-Dimensional printers – Principle – process parameters – process details –
machine details, Applications, and other concept modelers like thermo jet printers, Sander‟s
model maker, JP system 5, Object Quadra system
UNIT IV
Laser Engineering Net Shaping (LENS), Ballistic Particle Manufacturing (BPM): Principle. Introduction to rapid tooling – direct and indirect method, software for RP – STL files,
Magics, Mimics. Application of Rapid prototyping in Medical field.
UNIT V
Introduction to Virtual prototyping: End to end prototyping-simulation- components of virtual
prototyping- effects- economics of virtual prototyping.
Text Books:
1. Terry wohlers, Wohlers Report 2000, Wohlers Associates, USA, 2000.
2. Rapid Prototyping and manufacturing – Fundamentals of Streolithography, Paul F Jacobs,
Society of Manufacturing Engineering Dearborn, USA 1992.
References:
1. Pham, D.T. & Dimov.S.S., Rapid manufacturing, Springer-Verlag, London, 2001.
2. Joe Cecil, Virtual Engineering, Momentum Press, 2010
107
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME903MB: JOINING PROCESSES
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Weldability of plain carbon steels, alloy steels, cast irons, aluminium alloys. Pre and post
welding treatments, oxygen cutting, powder cutting arc and plasma cutting.
UNIT II
Fundamental principles of friction, friction stir and induction pressure welding, process
characteristics and applications
UNIT III
Explosive, diffusion and ultrasonic welding, principles of operation, process characteristics and
applications
UNIT IV
EBW: Heat generation and regulation, equipment details in typical set up, electron beam welding
in different degrees of vacuum,
LBW: Physics of lasers, types of lasers, operation of laser welding setup, advantages and
limitations, applications
UNIT V
Brazing: Wetting and spreading characteristics, surface tension and contact angle concepts,
brazing fillers, role of flux and characteristics, atmospheres for brazing,
Soldering: Techniques of soldering, solders, phase diagram, composition, applications, adhesive
bonding.
Text Book:
1. Schwartz M, Materials and Applications - Metal Joining Manual‟, McGraw-Hill, 1979.
References:
1. Nadkarni S.V., „Modern Arc Welding Technology‟, Oxford IBH Publishers, 1996.
2. Christopher Davis, „Laser Welding - A Practical Guide‟, Jaico Publishing House,1994.
3. Parmar R S, Welding Engineering and Technology, Khanna Publishers, 1997.
4. Welding technology by Little, Tata Mc.Grawhill, 2005.
5. Welding Handbook, American society of welding, 2007.
108
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME903MC: ADVANCED MATERIALS AND PROCESSING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Atoms molecules bonds in solids crystallinity defects in metallic
structure dislocations and plastic deformations fracture iron carbon equilibrium
diagrams steels and cast irons transformation.
UNIT II
Hardening in steelsTTT diagramsother heat treatment processes - formation of alloys in steel
and cast irons non ferrous alloys and their applications special alloys.
UNIT III Polymers and polymerization structure and properties of thermoplastics and thermosets
engineering applications property modifications mechanical, thermal behaviour
composites with polymer matrix
UNIT IV
Ceramics glasses glass ceramics fabrication methods- metal matrix and ceramic
matrix composites.
UNIT V
Processing of polymers fabrication of composites processing of
ceramicsthermal sprayingion beam machininglaser and electron beam processing superplastic
forming thin films and their deposition diamond coating techniques tribological applications.
Textbooks:
1. Material Science and Engineering by L.H.Van Vleck, 5th
edition, Addision Wealey(1985).
2. Structure and properties of Materials by R.M.Rose, L.A.Shepard and J.Wulff, Vol.1,4 John
Willey (1966) .
3. Essentials of Material Science by A.G.Guy, McGraw Hill(1976).
References:
1. The Science and Engineering Materials by D.R.Askeland. 2nd
Edition, Chapman and Hall
(1990).
2. Material Science and Engineering – An Introduction by William D. Callister, Jr., John Wiley
and Sons Inc., Fifth Edition, 2000.
3. R.E Small man and AHW Ngan, “Physical Metallurgy and advanced materials”, 7th edition,
Elsevier, 2007
109
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME903TA: FUEL CELL TECHNOLOGY
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Introduction: Basic Principles – Classification – Alkaline, Proton Exchange Membrane, Direct
Methanol, Phosphoric Acid & Molten Carbonate – Parts – Fuel cell poisoning
UNIT II
Thermodynamics: Basic Reactions, Heat of reaction, Enthalpy of formation of substances –
Enthalpy change of a reacting system – Gibbs free energy of substances – Gibbs free energy
change of reacting system – Efficiency – Power, heat due to entropy change, and internal ohmic
heating
UNIT III
Electrochemistry: Nernst equation and open circuit potential, pressure effect, temperature effect
–Stoichiometric coefficients and reactants utilization–Mass flow rate calculation–voltage and
current in parallel and serial connection–Over-potentials and polarizations–Activation
polarization–Tafel equation and exchange current density–lonic conductivity, catalysts,
Temperature and humidification effect, electro-osmotic drag effect
UNIT IV
Design & Optimisation: Geometries of fuel cells and fuel cell stacks – Rate of Diffusion of
reactants – Water flooding and water management – Gas delivery and current collection –
Bipolar plates design – Flow uniformity consideration – Optimization of gas delivery and current
collection/asymptotic power density-Heat Removal from Stack
UNIT V
Applications: Automotive applications & issues – Micro fuel cells & Portable power –
Distributed & Stationary power.
Text Books:
1. Fuel Cell Systems Explained, James Larminie and Andrew Dicks, 2nd Edition, John Wiley &
Sons Inc., 2000.
2. PEM Fuel Cells Theory and Practice, Frano Barbir, Elsevier Academic Press, 2005
110
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME903TB: FLUIDIZED BED SYSTEMS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Fluidized Bed Behaviour: Characterization of bed particles, comparison of different methods of
gas, solid contacts. Fluidization phenomena, regimes of fluidization, bed pressure drop curve.
Two phase and well-mixed theory of fluidization. Particle entrainment and elutriation, unique
features of circulating fluidized beds.
UNIT II
Heat Transfer: Different modes of heat transfer in fluidized bed, to wall heat transfer, gas to
solid heat Transfer, radiant heat transfer, heat transfer to immersed surfaces. Methods for
improvement, external heat exchangers, heat transfer and part load operations.
UNIT III
Combustion and Gasification: Fluidized bed combustion and gasification, stages of
combustion of particles, performance, start-up methods. Pressurized fluidized beds.
UNIT IV
Design Considerations: Design of distributors, stoichiometric calculations, heat and mass
balance, furnace design, design of heating surfaces, gas solid separators.
UNIT V
Industrial Applications: Physical operations like transportation, mixing of fine powders, heat
exchange, coating, drying and sizing. Cracking and reforming of hydrocarbons, carbonization,
combustion and gasification. Sulphur retention and oxides of nitrogen emission Control.
Text Books:
1. Howard,J.R., Fluidized Bed Technology: Principles and Applications, Adam Hilger, New
York, 1983.
2. Geldart, D., Gas Fluidization Technology, John Willey and Sons, 1986.
References:
1. Kunii, D and Levespiel, O., Fluidization Engineering, John Wiley and Son
2. Inc, New York, 1969.
3. Howard, J.R. (Ed), Fluidized Beds: Combustion and Applications, Applied Science
Publishers, New York, 1983
4. Botteril, J.S.M., Fluid Bed Heat Transfer, Academic Press, London, 1975.
5. Yates, J.G. Fundamentals of Fluidized bed Chemical Processes, Butterworths, 1983.
111
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME903TC: ADVANCED THERMODYNAMICS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Reversible work: Availability, Irreversibility and Second-Law Efficiency for a closed System
and Steady-State Control Volume. Availability. Analysis of Simple Cycles. Thermodynamic
Potentials, Maxwell relations, Generalized relations for changes in Entropy, Internal Energy and
Enthalpy, Generalised Relations for Cp and Cv Clausius Clayperon Equation , Kirchoff‟s
equation, Gibbs phase rule, Joule-Thomson Coefficient, Bridgman Tables for Thermodynamic
relations.
UNIT II
Real Gas Behaviour and Multi-Component Systems: Different Equations of State, Fugacity,
Compressibility, Principle of Corresponding States, Use of generalized charts for enthalpy and
entropy departure, fugacity coefficient, Lee-Kesler. Generalized three parameter tables.
Fundamental property relations for systems of variable Composition, partial molar properties,
Real gas mixtures, Ideal solution of real gases and liquids, Activity, Equilibrium in multi phase
systems, Gibbs phase rule for non-reactive components.
UNIT III
Chemical Thermodynamics and Equilibrium: Thermo chemistry, First Law analysis of
reacting systems, Adiabatic Flame temperature, Entropy Change of reacting systems, Second
Law analysis of reacting systems, Criterion for reaction Equilibrium composition, Chemical
availability, Availability of reacting systems.
UNIT IV
Statistical Thermodynamics: Microstates and Macro states, Thermodynamic probability,
Degeneracy of energy levels, Maxwell-Boltzmann, Fermi-Dirac and Bose-Einstein Statistics,
Microscopic Interpretation of heat and work, Evaluation of entropy, Partition function,
Calculation of the Macroscopic properties From partition functions, Equilibrium constant
statistical thermodynamic approach.
UNIT V
Irreversible Thermodynamics: Conjugate Fluxes and Forces, Entropy Production, Onsager's
Reciprocity relations, Thermoelectric Phenomena, formulations, Power Generation,
Refrigeration.
112
Text Books:
1. Holman, J.P., Thermodynamics, Fourth Edition, McGraw-Hill Inc.,1988.
2. S Kenneth Wark Jr.,Advanced Thermodynamics for Engineers, McGraw-Hill Inc., 1995.
3. Bejan,A., Advanced Engineering Thermodynamics, John Wiley and Sons,1988
References:
1. Smith, J.M. and Van Ness., H.C., Introduction to Chemical Engineering Thermodynamics,
Fourth Edition, McGraw-Hill Inc., 1987.
2. Sonntag, R.E., and Van Wylen, G, Introduction to Thermodynamics, Classical and
Statistical, Third Edition, John Wiley and Sons, 1991.
3. Sears, F.W.and Salinger G.I., Thermodynamics, Kinetic Theory and Statistical
Thermodynamics, Third edition, Narosa Publishing House,New Delhi, 1993.
4. DeHotf,R.T. Thermodynamics in Materials Science, McGraw-Hill Inc.,1993.
Rao,Y.V.C., Postulational and Statistical Thermodynamics, Allied Publisher Limited, NewDelhi,
1994.
113
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME904MA: PRODUCTION MANAGEMENT
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
INTRODUCTION: History and overview of production management - Capacity planning,
Location planning - Types of production processes. Layout planning - Productivity management.
UNIT II
INVENTORY MANAGEMENT: Deterministic and Probabilistic inventory management
models - Purchasing and warehousing, Methods study, Motion study and Work measurement -
Simple problems.
UNIT III
SCHEDULING: Job Evaluation - Wage incentive schemes - Value analysis - Forecasting -
Aggregate planning - Scheduling: Gantt charts and Sequencing - Simple problems.
UNIT IV
MRP: Project Management with PERT/CPM - Material requirements - Planning (MRP) -
Manufacturing - Resources planning (MRP II) - Enterprise resource planning (ERP)
UNIT V
TQM: Total Quality Management - Quality management systems - Statistical process control
(SPC) - Maintenance management - Reliability and maintenance, Replacement techniques,
Logistics and supply chain management.
Text Books:
1. Ahuja, K. K., Production Management, CBS Publishers, New Delhi, 1993
2. Goel, B. S., Production management, Pragathi & prakasam publishers, Meerut, 1984
References:
1. Hajra Nirjhar Roy, Production management, MP Publishers, New Delhi, 1990
2. Narang, G. B. S. and Kumar, V., Production management, Khanna publishers, New
Delhi, 1989
3. Agarwal and Jain, Production management, Khanna publishers, New Delhi, 1998
4. Levin and Richard, Production and operation management, Tata McGraw Hill
publications, New Delhi, 1990.
114
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME904MB: MANAGEMENT INFORMATION SYSTEMS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Organizations, Management and the Networked Enterprise Managing the Digital Firm:
Necessity of Information Systems (IS) - The New Role of IS in Organizations - New
Opportunities with Technology for IS. IS in the Enterprise: Major types, functional perspective
and enterprise applications. IS, organizations, management and strategy.
UNIT II
Information Technology Infrastructure Managing hardware and software assets:
Categories of computer systems, types of software, managing hardware and software assets.
Managing data resources: Telecommunications and Networks.
UNIT III
Management and Organizational Support Systems for the Digital Firm Managing
knowledge for the digital firm: Information and Knowledge Work Systems – Artificial
Intelligence - Other Intelligence Techniques. MIS and Decision Support System (DSS).
UNIT IV
Building Information Systems in the Digital Firm Redesigning the organization with IS:
Systems as planned organizational change – Business Process Reengineering (BPR) and process
improvement. Understanding the business value of systems.
UNIT V
Managing Change Importance of change management in IS success and failure – Managing
implementation.
Text Book:
1. Management Information Systems - Managing the Digital Firm. K.C.Laudon and J.P.Laudon,
8th Edition. PHI, 2004.
References:
1.An introduction to Data Base Management System by Data, C.J., Narosa Publication House,
New Delhi, 1985.
2. Information Systems for modern Management by Murdic, Ross and Clagget, PHI, 1985.
3.Management Information Systems – Conceptual Foundations by Davis Gordon, McGraw Hill,
1985.
115
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME904MC: DESIGN OF EXPERIMENTS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Introduction: The scientific method. The role of statistics in the advancement of science. The
phases of an experiment. Specifying the problem and the hypotheses. Experimental designs.
Analyses of experiments. Statistical inference. Estimation-Properties of estimators. Confidence
intervals. Hypothesis testing. The Z-test, the T-test, the X2-test, and the F-test. Sample size.
UNIT II
Completely Randomized Design: The one-factor experiments in a CRD. Linear model.
Partitioning of the total sum of squares. The analysis of variance table. Orthogonal contrasts.
Multiple range tests. Scheffe's test. Con- fidence intervals on means. Fixed and random models.
Estimation of variance components.Randomized Complete Block Design-The model and
assumptions. The ANOVA table. Tests after ANOVA.
UNIT III
Latin Square And Related Designs: Latin squares and two-way restrictions on randomization.
The linear model and assumptions for a one-factor experiment fitted in a Latin square design.
ANOVA table.
UNIT IV
Factorial Experiments: Complete factorial experiments in CRD's. Main effects and
interactions. One observation per treatment combination. Linear model and analysis. The error
term and pooling. The meaning of a significant interaction. The case of n observations per
treatment combination. Complete 2f factorial experiments in CRD's. Special notation. Average
effect of main effects and interaction. Orthogonal contrasts and sum of squares. Yates's
algorithm.
UNIT V
Fixed, Random And Mixed Models: One-and-two factor models. EMS rules. Pseudo-F tests.
Nested experiments:. Nested-factorial experiments. (Repeated-measures design and nested-
factorial experiments. Factorial experiments fitted in randomized complete block designs.
Text Books: 1. Hicks and Turner, Fundamental Concepts in the Design of Experiments, Oxford University
Press, 1999.
2. Douglas C. Montgomery, Design and Analysis of Experiments, John Wiley and Sons Inc.,
Eighth edition, 2012.
Reference:
1. Mark J. Anderson and Patrick J. Whitcomb, DOE Simplified: Practical Tools for Effective
Experimentation, Second Edition, Productivity Press, USA, 2007.
116
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME904TA: NUCLEAR ENGINEERING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Introduction to Nuclear Engineering: Introduction, Why Nuclear Power for Developing
Countries, Atomic Nuclei, Atomic Number and Mass Number, Isotopes, Atomic Mass Unit,
Radioactivity and Radioactive Change Rate of Radioactive Decay, Mass – Energy Equivalence,
Binding Energy, Release of Energy by Nuclear Reaction, types of Nuclear Reactions, Initiation
of Nuclear Reaction, Nuclear Cross – section, Nuclear Fission, The Fission Chain Reaction,
moderation, Fertile Materials and Breeding.
UNIT II
Nuclear Reactors: Introduction, General Components of Nuclear Reactor, General Problems of
Reactor Operation, Different Types of Reactors, Pressurised Water Reactors (PWR), Boiling
Water Reactors (BWR), Heavy Water – cooled and Moderated CANDU (Canadian Deuterium
Uranium) Type Reactors, Gas-cooled Reactors, Breeder Reactors, Reactor Containment Design,
Location of Nuclear Power Plant, Nuclear Power Station in India, India‟s 3-stage Programme
for Nuclear Power Development, Comparison Nuclear Plants with Thermal Plants.
UNIT III
Nuclear Materials: Introduction, Fuels, Uranium - production and purification of Uranium -
conversion to UF4 and UF6 - other fuels like Zirconium, Thorium - Beryllium. Cladding and
Structural Materials Coolants, Moderating and Reflecting Materials, Control Rod Materials,
Shielding Materials
UNIT IV
Nuclear Waste, reprocessing & Its Disposal: Introduction, Unit of Nuclear Radiation, Types
of Nuclear Waste, Nuclear fuel cycles - spent fuel characteristics - role of solvent extraction in
reprocessing - solvent extraction equipment Effects of Nuclear Radiation, Radioactive Waste
Disposal System, Gas Disposal System.
UNIT V
Safety Rules: Personal Monitoring, Radiation Protection (Radiation Workers, Non-Radiation
Workers, Public at large), Radiation Dose (Early effect, late effect, hereditary effect)
117
Text Books:
1. Glasstone, S. and Sesonske, A, Nuclear Reactor Engineering, 3rd
Ed, Von Nostrand, 1984.
2. Duderstadt, J.J. and Hamilton, L.J., Nuclear Reactor Analysis, John Wiley, 1976.
3. Walter, A.E. and Reynolds, A.B., Fast Breeder Reactor, Pergamon Press, 1981.
References:
1. Black / Veatch, “Power Plant Engineering”, CBS Published & Distributors.
2. P.K.Nag “ Power Plant Engineering”, Tata McGraw Hill Arora & Domkundwar “ Power
Plant Engineering “, Dhanpat Rai & Co.
3. Combined Power Plants by J.H.Horlock Pergamon Press.
118
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME904TB: SOLAR ENERGY TECHNOLOGY
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Source of radiation ,solar constant, solar charts , Measurement of diffuse, global and direct solar
radiation: pyrheliometer, pyranometer, pyregeometer, net pyradiometer, sunshine recorder.
UNIT II
Solar Non-Concentrating Collectors, Design considerations , Classification, air, liquid heating
collectors ,Derivation of efficiency and testing of flat plate collectors ,Analysis of concentric
tube collector , Solar green house.
UNIT III
Design, Classification, Concentrator mounting, focusing solar concentrators, Heliostats. Solar
powered absorption A/C system, water pump, chimney, drier, dehumidifier, still, cooker.
UNIT IV
Photo-voltaic cell, characteristics, cell arrays, power electric circuits for output of solar panels,
choppers, inverters, batteries, charge regulators, Construction concepts.
UNIT V
Energy Storage, Sensible, latent heat and thermo-chemical storage, pebble bed etc. materials for
phase change-Glauber‟s salt-organic compounds. Solar ponds.
Text Books:
1. D. Yogi Goswami, Frank Kreith, Jan. F. Kreider, “Principles of Solar Engineering”, 2nd
Edition, Taylor & Francis, 2000, Indian reprint, 2003
2. Edward E. Anderson, “Fundamentals for solar energy conversion”, Addison Wesley Publ.
Co., 1983.
References:
1. Duffie J. A and Beckman, W .A., “Solar Engineering of Thermal Process”, John Wiley,1991.
2. G. N. Tiwari and M. K. Ghosal, “Fundamentals of Renewable energy Sources”, Narosa
Publishing House, New Delhi, 2007
3. Energy Studies, Second Edition, by W. Shepherd and D. W. Shepherd, Imperial College
Press, London, 2004.
119
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME904TC: THERMAL MEASUREMENTS Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Analysis of experimental data: Types of Experimental Errors , Error Analysis on a
Commonsense Basis ,Uncertainty Analysis , Complicated Data Reduction , Statistical Analysis
of Experimental Data , Probability Distributions, The Gaussian or Normal Error Distribution ,
Comparison of Data with Normal Distribution The Chi-Square Test of Goodness of Fit, Method
of Least Squares , The Correlation Coefficient , Multivariable Regression , Standard Deviation of
the Mean , Student‟s t-Distribution , Graphical Analysis and Curve Fitting .
UNIT II
Flow Measurement: Introduction - Positive-Displacement Methods , Flow-Obstruction
Methods , Practical Considerations for obstruction Meters , The Sonic Nozzle , Flow
Measurement by Drag Effects , Hot-Wire and Hot-Film Anemometers , Magnetic Flow meters ,
Flow-Visualization Methods , The Shadowgraph ,The Schlieren , The Interferometer , The Laser
Doppler Anemometer (LDA) , Smoke Methods , Pressure Probes , Impact Pressure in Supersonic
Flow.
UNIT III
Measurement of Temperature: Introduction - Temperature Scales, The Ideal-Gas
Thermometer, Temperature Measurement by Mechanical Effects , Temperature Measurement by
Electrical Effects , Temperature Measurement by Radiation , Effect of Heat Transfer on
Temperature Measurement , Transient Response of Thermal Systems, Thermocouple
Compensation Temperature Measurements in High-Speed Flow
UNIT IV
Thermal and Nuclear Radiation Measurements: Thermal Conductivity of Liquids and Gases,
Measurement of Viscosity, Gas Diffusion ,Calorimeter, Convection Heat-Transfer
Measurements, Humidity Measurements, Heat-Flux Meters, pH Measurement, radiation
measurement- Thermal Radiation -Emissivity ,Reflectivity and Transmissivity, Solar Radiation
Measurements, Nuclear Radiation-Detection - The Geiger-Muller Counter, Photographic
Detection Methods, Ionization Chambers, photo graphic detection methods.
UNIT V
Measurements of Non-Newtonion Fluids: General viscous fluid; power law model, Ellis
model; Linear viscoelasticity; Nonlinear viscoelasticity, Rheometry: Shear rheometers,
Concentric cylinder rheometers, Cone & plate reheometer, Parallel plate rheometer, capillary
rheometer, slit rheometer; Extensional rheometry. Measurement in Complex flow, Pressure
measurement; Velocity measurement; Flow birefringence.
Text Books:
1. Thermal Measurements by J.P.Hollman
2. Fluid Mechanics Measurement -Edidted by R.J.Goldstein Hemisphere Pub.Corporation
120
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME905MA: COMPUTER INTEGRATED MANUFACTURING
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Introduction: Scope of computer integrated manufacturing, Product cycle, Production
automation.
Group technology: Role of group technology in CAD/CAM integration, Methods for
developing part families, Classification and coding, Examples of coding systems, Facility design
using group technology, Economics of group technology.
UNIT II:
Computer Aided Process Planning: Approaches to process planning - Manual, Variant,
Generative approach, Process planning systems - CAPP, DCLASS, CMPP, Criteria for selecting
a CAPP system, Part feature recognition, Artificial intelligence in process planning.
UNIT III:
Integrative manufacturing planning and control: Role of integrative manufacturing in
CAD/CAM integration, Over view of production control - Forecasting, Master production
schedule, Capacity planning, M.R.P., Order release, Shop-floor control, Quality assurance,
Planning and control systems, Cellular manufacturing, JIT manufacturing philosophy.
UNIT IV:
Computer Aided Quality Control: Terminology in quality control, Contact inspection methods,
Noncontact inspection methods, Computer aided testing, Integration of CAQC with CAD/CAM.
UNIT V:
Computer Integrated Manufacturing Systems: Types of manufacturing systems, Machine
tools and related equipment, Material handling systems, Computer control systems, FMS.
Text Books:
1. CAD/CAM Principles and Applications by P.N. Rao, 3rd
edition, Tata McGraw Hill
Publishing Company Ltd, 2010.
2. CAD/CAM Computer Aided Design and Manufacturing by Mikell P. Groover and Emory W.
Zimmer, Jr., Pearson Education India, 2008.
Reference:
1. Computer Integrated Design and Manufacturing by David D. Bedworth, Mark R. Henderson,
Philip M. Wolfe.
121
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME905MB: MACHINE TOOL DESIGN
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Introduction: Classification of Machine Tools, Working and Auxiliary Motions in Machine
Tools, Parameters Defining Working Motions of a Machine Tool, General Requirements of
Machine Tool Design.
UNIT II
Machine Tool Drives: Selection of Electrical Motor, Stepped and Stepless Output, Upper and
Lower limits of Machine Tools, Layouts of Intermediate Spindle Speeds, Selection of Values of
Common Ratio, Speed and Feed Gear box Design, Gearboxes with Clutched Drives, Feed in
Reciprocating Machines, Feed in Drilling Machines, Feed in Milling Machines, Feed in Lathe,
Cutting Screw Threads, Double-bound Gears, Mechanical Drives for Reciprocation. Stepless
Drives, Mechanical, Hydraulic, Electrical Stepless Drives.
UNIT III
Strength And Rigidity Of Machine Tool Structures: Design Criteria for Machine Tool
Structures, Static and Overall Compliance of Machine Tool, Design of Lathe Beds, Design of
Radial Drill Column, Force Analysis of a Shaping Machine Ram, Analysis of Straining Actions
on a Milling Machine Structure, Analysis and Design of Tailstock Assembly.
UNIT IV
Analysis Of Guideways And Power Screws: Design of Slideways for Wear Resistance, Design
of Slideways for Stiffness, Guideways Operating under Liquid Friction Conditions, Design of
Power Screws.
UNIT V
Analysis Of Spindles And Spindle Supports: Functions of Spindle Unit and Requirements,
Design calculations of Spindles, Sliding Bearings, Hydrodynamic and Hydrostatic Journal
Bearings.
Text Books: 1. G C Sen, A Bhattacharyya, Principles of Machine Tools, New Central Book Agency, 2009.
2. N K Mehta, Machine Tool Design and Numerical Control, Tata McGraw-Hill, 2nd
edition,
2010.
References: 1. N Acherken, Machine Tool Design, Vol. I-IV, University press of the pacific, 2000.
2. Brandon C. Gegg, C. Steve Suh, Albert C. J. Luo, Machine Tool Vibrations and Cutting
Dynamics, Springer, 2011.
122
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME905MC: DESIGN OF MATERIAL HANDLING SYSTEMS
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Flexible Hoisting Appliances: Type, selection and applications of material handling
equipments, choice of material handling equipment – hoisting equipment – components and
theory of hoisting equipment – chain and ropes – selection of ropes, pulleys, pulley systems,
sprockets and drums.
UNIT II
Load Handling Equipments And Brakes: Forged standard hooks – forged Ramshorn hooks –
solid triangular eye hooks – crane grabs, electric lifting magnetic – grabbing attachments for
loose materials. arresting gear – brakes: shoe, band and cone types – elements of shoe brakes –
thermal calculation in shoe brakes.
UNIT III
Surface And Overhead Transportation Equipments: Hand operated trucks – powered trucks
– tractors – electronically controlled tractors - hand truck on rails – industrial railroad
equipments: locomotives - winches – capstans – turntables – monorail conveyors –pipe rail
systems – flat bar monorails. Rail traveling mechanism, cantilever and monorail cranes,
cogwheel drive, monocable tramways- reversible tramways.
UNIT IV
Elevating Equipments: Continuous-motion vertical conveyors – reciprocating-motion vertical
conveyors – stackers – work levelers and tail gates – industrial lifts – passenger lifts – freight
elevators – mast type elevators – vertical skip hoist elevators, bucket elevators: design, loading
and bucket arrangements.
UNIT V
Conveying Equipments: Belt conveyors - chain conveyors – apron conveyors – escalators –
flight conveyors – roller conveyors - oscillating conveyors. design of belt conveyors, screw
conveyors and pneumatic conveyors.
Text Books:
1. Rudenko. N., Materials Handling Equipment – MIR Publishers, 1969
2. Spivakovsky. A.O and Dyachkov. V.K., Conveying Machines, Volume I and II, MIR
Publishers, 1985
References:
1. Alexandrov, M., Materials Handling Equipments, MIR Publishers, 1981
2. Boltzharol, A., Materials Handling Handbook, The Ronald Press Company, 1958.
123
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME905TA: THERMAL TURBO MACHINERY
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
General Concepts Related to Turbo Machinery: Classification; Euler's Equation for Turbo
machinery; Velocity triangle; Cascade analysis & nomenclature. Shaft Power & Aircraft
Propulsion Cycles
UNIT II
Centrifugal Compressors: Work done and pressure rise; Slip; Compressibility effects;
Compressor characteristics. Axial Flow Compressors: Stage pressure rise; Blockage in
compressor annulus; Degree of reaction; 3- D flow; Stage performance; h-s diagram &
efficiency; off design performance; Performance characteristics; Design process. Combustion
System.
UNIT III
Axial and Radial Flow Turbines: Elementary theory of axial flow turbines - stage parameters-
multi-staging – stage Loading and flow coefficients - degree of reaction - stage temperature and
pressure Ratios – single and twin spool arrangements – performance. Matching of components.
Blade Cooling, Radial flow turbines.
UNIT IV
Analysis of Centrifugal Blowers and Fans: Centrifugal Blowers: Theoretical characteristic
curves, Euler‟s characteristics and Euler‟s velocity triangles, losses and hydraulic efficiency,
flow through impeller inlet volute, diffusers, leakage disc friction mechanical losses multi vane
impellers of impulse type, cross flow fans.
UNIT V
Testing and Control of Fans: Fan testing, noise control, materials and components blower
regulation, speed control, throttling, control at discharge and inlet.
Text Books:
1. Ganesan, V. Gas Turbines, Tata McGraw-Hill, 1999.
2. Fluid Mechanics, Thermodynamics of Turbo machinery, S.L. Dixon, 4th Edition, Pergamon
Press, 1998
References:
1. Austin H. Church, Centrifugal pumps and blowers, John Wiley and Sons, 1980
2. Mattingly J D, Elements of Gas turbine Propulsion, McGraw Hill, 1st Edition.1997
3. Gas Turbine Theory, H. Cohen, 4th Edition, Longman, 2000.
4. S.M. Yahya, “Fundamentals of Compressible Flow ", New Age International (P) Limited,
New Delhi, 1996
124
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME905TB: MULTIPHASE FLOW
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals: 40 Marks
UNIT I
Introduction- multi phase and multi-component flow, practical examples; method of analysis of
multi phase and multi-component flow problems; basic definitions; two phase, one-dimensional
conservation equations; pressure gradient components; flow patterns.
UNIT II
Basic flow models – homogeneous flow model, pressure gradient, two phase friction factor for
laminar flow and turbulent flow, two phase viscosity, friction multiplier; separated flow model –
pressure gradient, Lokhart Martinelli correlation.
UNIT III
Drift flux model – gravity dominated flow regime, corrections for void fraction and velocity
distribution in different flow regimes, pressure loss due to multi phase flow in pipe fittings,
velocity and concentration profiles in multi phase flow; one-dimensional waves in two
component flow.
UNIT IV
Boiling– evaporation, nucleate boiling, convective boiling; bubble formation and limiting
volume; boiling map; DNB; critical boiling conditions.
UNIT V
Condensation process – types of condensation, Nusselt theory, deviations from Nusselt theory,
practical equations, condensation of flowing vapors.
Text Books:
1. Hewitt, G., Delhaye, J. M., and Zuber, N., Multiphase Science and Technology, Vol. I,
McGraw-Hill, 1982
2. Collier, J. G., Convective Boiling and Condensation, McGraw-Hill, 1981.
References:
1. Wallis, G. W., One-dimensional Two Phase Flow, McGraw-Hill, 1969.
2. Stephen, K. Heat Transfer in Condensation and Boiling, Berlin Hiedelberg, 1992.
3. Hsu, Y. Y. and Graham, R. W., Transport Processes in Boiling and Two phase Systems,
McGraw-Hill, 1976.
4. Ginoux, J. J., Two Phase Flows and Heat Transfer, McGraw-Hill, 1978.
125
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME905TC: ADVANCED IC ENGINES
Hours per week: 4 End Examination: 60 Marks
Credits: 4 Sessionals:40 Marks
UNIT I
Alternate Fuels for IC engines: Introduction - Possible Alternatives - Alcohols, hydrogen,
LPG, CNG, Gaseous fuels, vegetable oils, Biomass- Merits and demerits. Solid Fuels, Liquid
Fuels- Alcohols for SI Engines reformulated Gasoline for SI Engine, Alcohol for CI Engine
Surface-Ignition Alcohol CI Engine Spark-Assisted Diesel. Gaseous Fuels-Hydrogen Engines,
Natural Gas, Compressed Natural Gas (CNG), Liquefied Petroleum Gas (LPG) relative merits
and demerits of gaseous fuels. Future Scenario for LPG Vehicles, Dual Fuel Operation, Other
Possible Fuels, Biogas, Producer Gas, Blast Furnace Gas, Coke Oven Gas, Benzol, Acetone and
Diethyl Ether
UNIT II
Thermodynamics and Kinetics of Combustion: Properties of mixture – combustion
stoichiometry – chemical energy – chemical equilibrium and criteria – properties of combustion
products. First law combustion calculations – adiabatic flame temperature (analytical and
graphical methods) – simple second law analysis. Elementary reactions – chain reactions – pre-
ignition kinetics – global reactions – kinetics – reaction at solid surface,
UNIT III
Theory of combustion: Spray formation and droplet behavior, direct and indirect Injection
combustion in IC engines premixed charge engine combustion, Stages of combustion for IC
Engines- rate of pressure rise- p-θ diagram, heat release rates calculations- S.I. engine cycle
calculations, combustion chambers for MPFI, Design Considerations for Combustion Chambers
of IC engines.
UNIT IV
Engine performance and Emissions: Methods of performance improvement, Engine dynamics
and torque analysis, Use of Combustion chart, Analytical method of performance estimation,
supercharging, emission norms, emissions control by engine modifications, emission after
treatment, exhaust system devices, catalytic converters, thermal reactors, Emissions from engines
operating on Alternative fuels
UNIT V
Modern Vehicle Technologies: Mean Value S.I. Engine Modeling, Variable Cam Timing
Engine, Microprocessor controls in engines, low heat rejection engines, Multi fuel engines,
Layout of an electric vehicle - Advantage and limitations- Hybrid vehicle - Solar powered
vehicles.
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Text Books:
1. Internal Combustion Engine Fundamentals, John B. Heywood, First Edition, McGraw Hill,
2. Internal Combustion Engines, V. Ganesan, Tata McGraw Hill, Second Edition Mathur, M. L.
and Sharma, R. P., Internal Combustion Engines, Dhanpath Rai & Sons, 2005
References: 1. Stephen R. T., An Introduction to Combustion, McGraw-Hill International Editions
2. Kuo, K. K., Principles of Combustion, John Willey & Sons, 1986.
3. Mukunda, H. S., Understanding Combustion, Macmillan India Ltd., 1992.
4. Smith, M. L. and Stinson, K. W., Fuels and Combustion, McGraw-Hill, 1952.
5. Ashley S. C., Thermodynamic Analysis of Combustion Engines, John Wiley, 1979.
6. Samir Sarkar, Fuels and Combustion, 2nd Edition, Orient Longman, 1990
127
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME911M: FINITE ELEMENT METHODS LAB
Hours per week: 3 Continuous evaluation: 100 Marks
Credits: 2
1. Introduction to Finite Element Analysis software – ANSYS / NISA / Nastran
2. Static Structural Analysis of 1D problems – bars, trusses, beams and frames
3. Static Structural Analysis of 2D problems – plane stress, plane strain, axisymmetric
4. Static Structural Analysis of 3D problems – various brackets
5. Dynamic Structural Analysis of 1D problems – beams and frames
6. Steady State Thermal Analysis of 1D and 2D models
7. Transient Thermal Analysis of 1D and 2D models
8. Couple Field (Thermal/Structural) Analysis
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Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Ninth Semester
EIRME911T: COMPUTATIONAL FLUID DYNAMICS LAB
Hours per week: 3 Continuous evaluation: 100 Marks
Credits: 2
1. Solving Thermal Engineering problems for Inviscid incompressible 2-D Flow.
2. Incompressible Laminar viscous flow with and without heat transfer
3. 2-D incompressible laminar Boundary Layer without heat transfer.
4. 2-D incompressible turbulent Boundary Layer with and without heat transfer.
5. Steady and unsteady heat conduction in 2-D, using available packages such as TK Solver,
ANSYS, CFX, STARCD, FLUENT etc…
Five Year Dual degree (B. Tech + M.Tech)
Mechanical Engineering- Tenth Semester
EIRME-1011: PROJECT-2
Hours per week: 24 End Examination: 50 Marks
Credits: 16 Sessionals: 50 Marks