department of mechanical engineering me_course...department of mechanical engineering course...
TRANSCRIPT
Department of Mechanical Engineering
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 2
RSET VISION
RSET MISSION
To evolve into a premier technological and research institution,
moulding eminent professionals with creative minds, innovative
ideas and sound practical skill, and to shape a future where
technology works for the enrichment of mankind.
To impart state-of-the-art knowledge to individuals in various
technological disciplines and to inculcate in them a high degree of
social consciousness and human values, thereby enabling them to
face the challenges of life with courage and conviction.
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 3
DEPARTMENT VISION
DEPARTMENTMISSION
To evolve into a centre of excellence by imparting professional
education in mechanical engineering with a unique academic and
research ambience that fosters innovation, creativity and excellence.
To have state-of-the-art infrastructure facilities.
To have highly qualified and experienced faculty from
academics, research organizations and industry.
To develop students as socially committed professionals with
sound engineering knowledge, creative minds, leadership
qualities and practical skills.
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 4
PROGRAMME EDUCATIONAL OBJECTIVES
PROGRAMME OUTCOMES
PEO 1: Demonstrated the ability to analyze, formulate and solve/design
engineering/real life problems based on his/her solid foundation in mathematics,
science and engineering.
PEO 2: Showcased the ability to apply their knowledge and skills for a
successful career in diverse domains viz., industry/technical, research and higher
education/academia with creativity, commitment and social consciousness.
PEO 3: Exhibited professionalism, ethical attitude, communication skill, team
work, multidisciplinary approach, professional development through continued
education and an ability to relate engineering issues to broader social context.
1) Engineering Knowledge: Apply the knowledge of Mathematics, Science,
Engineering fundamentals, and Mechanical Engineering to the solution of
complex engineering problems.
2) Problem analysis: Identify, formulate, review research literature, and
analyze complex Engineering problems reaching substantiated conclusions
using first principles of mathematics, natural sciences, and Engineering
sciences.
3) Design/development of solutions: Design solutions for complex Engineering
problems and design system components or processes that meet the specified
needs with appropriate consideration for the public health and safety, and the
cultural, societal, and environmental considerations.
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 5
4) Conduct investigations of complex problems: Use research based knowledge
and research methods including design of experiments, analysis and
interpretation of data, and synthesis of the information to provide valid
conclusions.
5) Modern tool usage: Create, select, and apply appropriate techniques, resources,
and modern engineering and IT tools including prediction and modeling to
complex Engineering activities with an understanding of the limitations.
6) The Engineer and society: Apply reasoning informed by the contextual
knowledge to assess societal, health, safety, legal and cultural issues and the
consequent responsibilities relevant to the professional Engineering practice.
7) Environment and sustainability: Understand the impact of the professional
Engineering solutions in societal and environmental contexts, and demonstrate
the knowledge of, and the need for sustainable developments.
8) Ethics: Apply ethical principles and commit to professional ethics and
responsibilities and norms of the Engineering practice.
9) Individual and team work: Function effectively as an individual, and as a
member or leader in diverse teams, and in multidisciplinary settings.
10) Communication: Communicate effectively on complex Engineering
activities with the Engineering Community and with society at large, such as,
being able to comprehend and write effective reports and design documentation,
make effective presentations, and give and receive clear instructions.
11) Project management and finance: Demonstrate knowledge and
understanding of the Engineering and management principles and apply these to
one’s own work, as a member and leader in a team, to manage projects and in
multi-disciplinary environments.
12) Life -long learning: Recognize the need for, and have the preparation and
ability to engage in independent and life- long learning in the broadest context
of technological change.
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 6
PROGRAMME SPECIFIC OUTCOMES
Mechanical Engineering Programme Students will be able to:
1) Apply their knowledge in the domain of engineering mechanics, thermal
and fluid sciences to solve engineering problems utilizing advanced
technology.
2) Successfully apply the principles of design, analysis and implementation
of mechanical systems/processes which have been learned as a part of the
curriculum.
3) Develop and implement new ideas on product design and development
with the help of modern CAD/CAM tools, while ensuring best
manufacturing practices.
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 7
INDEX PAGE
NO: 1. SEMESTER PLAN 8
2. ASSIGNMENT SCHEDULE 9
3. SCHEME 10
4. ME ME302 HEAT AND MASS TRANSFER 11
4.1. COURSE INFORMATION SHEET
4.2. COURSE PLAN
4.3 SAMPLE QUESTIONS
5. ME304 DYNAMICS OF MACHINERY 21
5.1. COURSE INFORMATION SHEET
5.2. COURSE PLAN
5.3 SAMPLE QUESTIONS
6. ME306 ADVANCED MANUFACTURING TECHNOLOGY 33
6.1. COURSE INFORMATION SHEET
6.2. COURSE PLAN
6.3 SAMPLE QUESTIONS
7. ME308 COMPUTER AIDED DESIGN AND ANALYSIS 43
8.1. COURSE INFORMATION SHEET
8.2. COURSE PLAN
8.3 SAMPLE QUESTIONS
8. ME312 METROLOGY AND INSTRUMENTATION 53
9.1. COURSE INFORMATION SHEET
9.2. COURSE PLAN
9.3 SAMPLE QUESTIONS
9. ME364 Turbo Machinery 66
10.1. COURSE INFORMATION SHEET
10.2. COURSE PLAN
10.3 SAMPLE QUESTIONS
10. ME372 Operations Research 74
11.1. COURSE INFORMATION SHEET
11.2. COURSE PLAN
11. ME332 Computer Aided Design & Analysis Lab 83
12.1. COURSE INFORMATION SHEET
12.2. COURSE PLAN
12.3 SAMPLE QUESTIONS
12. ME334 Manufacturing Technology Lab II 90
13.1. COURSE INFORMATION SHEET
13.2. COURSE PLAN
13.3 SAMPLE QUESTIONS
13. ME352 Comprehensive Exam 99
14.1. COURSE INFORMATION SHEET
14.2. COURSE PLAN
14.3 SAMPLE QUESTIONS
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 8
SEMESTER PLAN
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 9
ASSIGNMENT SCHEDULE
Week 4 ME302 Heat & Mass Transfer
Week 5 ME304 Dynamics of Machinery
Week 5 ME306 Advanced Manufacturing Technology
Week 6 ME308 Computer Aided Design and Analysis
Week 7 ME312 Metrology and Instrumentation
Week 8 ME332 Computer Aided Design & Analysis Lab
Week 8 ME364 Turbo Machinery
Week 9 ME372 Operations Research
Week 9 ME302 Heat & Mass Transfer
Week 12 ME304 Dynamics of Machinery
Week 12 ME306 Advanced Manufacturing Technology
Week 13 ME308 Computer Aided Design and Analysis
DEPARTMENT OF MECHANICAL ENGINEERING
COURSE HANDOUT: S6 Page 10
SCHEME
Code Subject
Hours/week
Credits Exam
Slot L T P/D
ME302 Heat & Mass Transfer 3 1 0 4 A
ME304 Dynamics of Machinery 2 1 0 3 B
ME306 A Advanced Manufacturing Technology 3 0 0 3 C
ME308 Computer Aided Design and Analysis 3 0 0 3 D
ME312 Metrology and Instrumentation 3 0 0 3 E
ME364 ME364 Turbo Machinery(Elective 1) 3 0 0 3 F
ME 372 Operations Research(Elective 2) 3 0 0 3 F
ME332 Computer Aided Design & Analysis
Lab 2 1 0 3 S
ME334 Manufacturing Technology Lab II 0 0 3 3 T
ME352 Comprehensive Exam 0 1 1 2 U
Total 19 4 4 27
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 11
4. ME 302 HEAT AND MASS TRANSFER
4.1 COURSE INFORMATION SHEET
PROGRAMME: ME DEGREE: BTECH
COURSE: HEAT AND MASS TRANSFER SEMESTER: 6 CREDITS: 4
COURSE CODE: ME 302
REGULATION: 2016
COURSE TYPE: CORE
COURSE AREA/DOMAIN: THERMAL &
FLUID SCIENCE
CONTACT HOURS: 3+1 (Tutorial)
Hours/Week.
CORRESPONDING LAB COURSE CODE
(IF ANY): ME 431
LAB COURSE NAME: MECHANICAL
ENGINEERING LAB
SYLLABUS:
UNIT DETAILS HOURS
I
Modes of Heat Transfer: Conduction: Fourier law of heat conduction -
Thermal conductivity of solids, liquids and gases, Factors affecting thermal
conductivity. Most general heat conduction equation in Cartesian, cylindrical
and spherical coordinates. One dimensional steady state conduction with and
without heat generation through plane walls, cylinders and spheres - variable
thermal conductivity. Conduction shape factor - heat transfer through corners
and edges. Critical radius of insulation.
12
II
Elementary ideas of hydrodynamics and thermal boundary layers -Thickness
of Boundary layer - Displacement, Momentum and Energy thickness
(description only). Convection heat transfer: Newton’s law of cooling -
Laminar and Turbulent flow, Reynolds Number, Critical Reynolds Number,
Prandtl Number, Nusselt Number, Grashoff Number and Rayleigh’s Number.
Dimensional analysis Buckingham’s Pi theorem- Application of dimensional
analysis to free and forced convection- empirical relations- problems using
empirical relations
10
III
Transient heat conduction-lumped heat capacity method. Fins: Types of fins -
Heat transfer from fins of uniform cross sectional area- Fin efficiency and
effectiveness. Boiling and condensation heat transfer (elementary ideas only),
Introduction to heat pipe.
8
IV
Combined conduction and convection heat transfer-Overall heat transfer
coefficient - Heat exchangers: Types of heat exchangers, AMTD, Fouling
factor, Analysis of Heat exchangers- LMTD method, Correction factor,
Effectiveness-NTU method, Special type of heat exchangers (condenser and
evaporator, simple problems only)
8
V
Radiation- Nature of thermal radiation-definitions and concepts-
monochromatic and total emissive power-Intensity of radiation- solid angle-
absorptivity, reflectivity and transmissivity-Concept of black body- Planck’
law- Kirchoff’s law- Wein’s displacement law-Stefan Boltzmann’s law-
black, gray and real surfaces-Configuration factor (derivation for simple
geometries only)- Electrical analogy- Heat exchange between black/gray
surfaces- infinite parallel plates, equal and parallel opposite plates-
perpendicular rectangles having common edge- parallel discs (simple
problems using charts and tables). Radiation shields (no derivation).
10
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 12
VI
Mass Transfer: Mass transfer by molecular diffusion- Fick’s law of diffusion-
diffusion coefficient, Steady state diffusion of gases and liquids through solid
- equimolar diffusion, Isothermal evaporation of water through air- simple
problems. Convective mass transfer- Evaluation of mass transfer coefficient-
empirical relations- simple problems- analogy between heat and mass transfer
8
TOTAL HOURS 56
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
T Sachdeva R C, Fundamentals of Engineering Heat and Mass Transfer, New Age Science
Limited, 2009
T R.K.Rajput, Heat and mass transfer, S.Chand & Co.,2015
T Kothandaraman C.P., Fundamentals of Heat and Mass Transfer, New Age
International, New Delhi, 2006
T P. K. Nag, Heat and Transfer, McGraw-Hill, 2011
R Frank P. Incropera and David P. Dewitt, Fundamentals of Heat and Mass Transfer,
John Wiley & Sons, 2011
R J. P. Holman, Heat Transfer, McGraw Hill, 2011
R M. Necati Ozisick, Heat Transfer A Basic Approach, McGraw Hill Book Company
R Yunus A. Cengel, Heat Transfer - A Practical Approach, McGraw-Hill Education.
R S. P. Sukhatme, A Text Book on Heat Transfer, Universities Press, Hyderabad.
Data Book:
Heat and Mass Transfer data book: C.P. Kothandaraman, S. Subramanya, New age
International publishers, 2014
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
C.CODE COURSE NAME DESCRIPTION SEM
ME 203 Mechanics of Fluids Knowledge about the basics of boundary layer
theory and Dimensional Analysis. 3
MA 102 Differential Equations Knowledge about basics of partial differential
equations. 2
ME 205 Thermodynamics Knowledge about basic concepts of
Thermodynamics. 3
COURSE OBJECTIVES:
1 To introduce the various modes of heat transfer and to develop methodologies for solving a
wide variety of practical heat transfer problems.
2 To provide useful information concerning the performance and design of simple
heat transfer systems
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 13
3 To introduce mass transfer
COURSE OUTCOMES:
SL. NO. DESCRIPTION
Bloom’s
Taxonomy
Level
C302.1 Solve problems involving steady state heat conduction with and
without heat generation in simple geometries.
Apply
(level 3)
C302.2 Evaluate heat transfer coefficients for Natural convection and
Forced convection situations using empirical relations.
Analyze
(level 4)
C302.3 Design Heat Exchangers and Fins and evaluate its performance. Evaluate
(level 5)
C302.4 Solve problems involving transient heat conduction and Understand
the basics of Heat pipe, Boiling and Condensation
Apply
(level 3)
C302.5 Estimate radiation heat transfer between black body and gray body
surfaces.
Analyze
(level 4)
C302.6 Solve problems involving mass transfer due to diffusion, chemical
reaction and convection.
Apply
(level 3)
CO-PO AND CO-PSO MAPPING
PO
1
PO
2
PO
3
PO
4
PO
5
PO
6
PO
7
PO
8
PO
9
PO
10
PO
11
PO
12
PSO
1
PSO
2
PSO
3
C302.1 2 2 - - - - - - - - - - 2 - -
C302.2 - 2 2 - - 2 2 - - - - - 2 - -
C302.3 2 1 1 - - 2 2 - - - - - 2 - -
C302.4 2 2 - - - - - - - - - - 2 - -
C302.5 2 2 2 - - - 2 - - - - - 2 - -
C302.6 - - - - - 3 3 - - - - - 2 - -
JUSTIFICATIONS FOR CO-PO MAPPING
MAPPING
LOW/MEDIUM
/
HIGH
JUSTIFICATION
C302.1-PO1 M
Students will be able to appreciate and to a considerable
extent solve complex engineering problems related to steady
state heat conduction with and without heat generation in
simple geometries, based on acquired knowledge.
C302.1-PO2 M
Problem analysis based on first principles of mathematics
and engineering sciences is essential to analyze complex
engineering problems related to steady state heat conduction
with and without heat generation.
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 14
C302.2-PO2 M
Problem analysis based on first principles of mathematics
and research based relevant data is essential to evaluate
heat transfer coefficients for Natural convection and Forced
convection situations.
C302.2-PO3 M
In the design/development of solutions for complex heat
convection problems and to design heat transfer equipment
that consider the public health and safety, the knowledge
about various dimensionless numbers is a definite
prerequisite.
C302.2-PO6 M
Gained knowledge of various convection problems will help
the students to develop heat transfer equipment which is
beneficial for the society.
C302.2-PO7 M
Students can develop products in a sustainable manner by
understanding the impact of the convection heat transfer
solutions in societal and environmental contexts.
C302.3-PO1 M
Students will be able to solve complex engineering problems
related to heat exchangers and fins, based on acquired
knowledge.
C302.3-PO2 L
Problem analysis based on first principles of mathematics
and research based relevant data is essential to design
various heat exchangers and fins.
C302.3-PO3 L
In the design/development of solutions for complex heat
exchanger problems and to design proper fins that consider
the public safety, the knowledge about various types of heat
exchangers and fins is essential.
C302.3-PO6 M
Gained knowledge of various heat exchangers and fins will
help the students to develop heat transfer equipment which
is beneficial for the society.
C302.3-PO7 M Students can develop heat exchangers in a sustainable
manner by considering environmental/societal impact.
C302.4-PO1 M
Analytical knowledge on the transient heat conduction,
condensation and boiling helps the students to solve various
real life heat transfer problems.
C302.4-PO2 M
Problem analysis based on first principles of mathematics
and research based relevant data is essential to analyze
complex engineering problems related to transient heat
conduction, condensation and boiling.
C302.5-PO1 M
Students will be able to solve complex engineering problems
related to radiation heat transfer, based on acquired
knowledge.
C302.5-PO2 M
Problem analysis based on first principles of mathematics
and research based relevant data is essential to estimate
radiation heat exchange between black and gray body
surfaces.
C302.5-PO3 M
Knowledge in various laws of radiation heat transfer is
essential for the design/development of equipment which
uses radiation heat exchange.
C302.5-PO7 M
Gained knowledge in various laws of radiation heat transfer
will help the students to develop products which uses solar
energy in a sustainable manner.
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 15
C302.6-PO6 H
Knowledge about various modes of mass transfer will help
the students to develop products which is beneficial for the
society.
C302.6-PO7 H
Knowledge in various modes of mass transfer will help to
develop mass transfer equipment by considering
environmental impact.
JUSTIFICATIONS FOR CO-PSO MAPPING
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL REQUIREMENTS:
SNO DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
1 Introduction to Finite Difference Method and Fundamentals of
CFD 1, 2, 5\1
Web source
reference 2
PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC
TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN: NIL
WEB SOURCE REFERENCES:
1 http://nptel.ac.in/courses/112101097/7,
https://www.youtube.com/watch?v=2AQ6iQc3_R8
2 http://nptel.ac.in/courses/112104030/#
2 http://nptel.ac.in/courses/112101097/
3 http://www.nptelvideos.in/2012/12/heat-and-mass-transfer.html
4 https://www.youtube.com/watch?v=tDs4cFOqTdM
5 https://www.youtube.com/watch?v=SNnd0f3xXlg
MAPPING LOW/MEDIUM/
HIGH JUSTIFICATION
C302.1-
PSO1 M
Students will acquire basic knowledge on various modes
of heat transfer and will be able to apply this knowledge
to solve conduction heat transfer problems.
C302.2-
PSO1 M
Deeper knowledge gained into the significance of
dimensional analysis will help to solve complex
engineering problems related to convection heat transfer.
C302.3-
PSO1 M
The acquired knowledge on various modes of heat
transfer will helps the students to design heat exchangers
and fins.
C302.4-
PSO1 M
Students can apply their knowledge in transient heat
conduction to solve engineering problems.
C302.5-
PSO1 M
The acquired knowledge on various laws of radiation
heat transfer will helps the students to design equipment
which uses solar energy.
C302.6-
PSO1 M
Students can apply their knowledge in various modes of
mass transfer to solve engineering problems.
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 16
6 https://www.youtube.com/watch?v=QMg3vr7KgDA
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☐ CHALK & TALK ☐ STUD. ASSIGNMENT ☐ WEB
RESOURCES
☐LCD/SMART
BOARDS
☐ STUD.
SEMINARS
☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD.
SEMINARS
☐ TESTS/MODEL
EXAMS
☐ UNIV.
EXAMINATION
☐ STUD. LAB
PRACTICES
☐ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐
CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☐ ASSESSMENT OF COURSE OUTCOMES
(BY FEEDBACK, ONCE)
☐ STUDENT FEEDBACK ON FACULTY
(TWICE)
☐ ASSESSMENT OF MINI/MAJOR
PROJECTS BY EXT. EXPERTS
☐ OTHERS
4.2 COURSE PLAN
DAY MODULE TOPIC PLANNED
1 I Introduction to HT, Conduction, Convection and Radiation
2 I Fourier law, Thermal conductivity of solids, liquids and gases, Factors
affecting thermal conductivity
3 I Most general heat conduction equation in Cartesian & Cylindrical
coordinates
4 I 1D steady state conduction through composite walls
5 I 1D steady state conduction through composite cylinders
6 I 1D steady state conduction through composite spheres
7 I 1D steady state heat conduction with heat generation through plain walls
8 I 1D steady state heat conduction with heat generation through cylinders and
spheres
9 I Thermal resistance and contact resistance
10 I Critical radius of insulation
11 I Overall heat transfer coefficient
12 I Conduction shape factor-heat transfer through corners and edges
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 17
13 II Elementary ideas of hydrodynamics and thermal boundary layers -
Thickness of Boundary layer
14 II Convection heat transfer: Newton’s law of cooling, factors affecting HTC
in forced and natural convection
15 II Significance of dimensionless numbers
16 II Dimensional analysis to Free convection
17 II Dimensional analysis to Forced convection
18 II Forced convection in a circular pipe
19 II Forced convection HT over a flat plate
20 II Forced convection HT across cylinders
21 II Free convection HT from a plate kept vertical and horizontal
22 II Free convection HT from a cylinder kept vertical and horizontal
23 III Transient heat conduction-lumped heat capacity method
24 III Fins: Types of fins, Governing equations and boundary conditions
25 III Heat transfer from fins of uniform cross sectional area: Infinitely long fin
26 III Heat transfer from fins of uniform cross sectional area: Fin insulated at the
tip
27 III Heat transfer from fins of uniform cross sectional area: Heat loss by
convection at the tip
28 III Fin efficiency and effectiveness
29 III Boiling and condensation heat transfer
30 III Introduction to heat pipe
31 IV Heat exchangers: Types of heat exchangers
32 IV AMTD, Fouling factor
33 IV LMTD for parallel flow Heat exchanger
34 IV LMTD for counter flow Heat exchanger
35 IV Effectiveness-NTU for parallel flow
36 IV Effectiveness-NTU for counter flow
37 IV Special type of heat exchangers: condenser and evaporator
38 IV Numerical problems
39 V Radiation HT: definitions and concepts
40 V Monochromatic and total emissive power-Intensity of radiation- solid angle
41 V Absorptivity, reflectivity and transmissivity-Concept of black body
42 V Steffan Boltzman law, plank's law, Kirchoff's law and Wein's displacement
law.
43 V Configuration factor (Shape factor) of simple geometries
44 V Heat exchange by radiation between black surfaces - equal, parallel and
opposite squares
45 V Heat exchange by radiation between black surfaces - rectangles
perpendicular to each other having common edge
46 V Heat exchange between grey bodies- infinite parallel planes of different
emissivity - grey body factor
47 V Electrical network analogy in radiation problems - equivalent emissivity or
interchange factor
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 18
48 V Radiation shield
49 VI Mass transfer: Introduction, Fick's law, diffusion coefficient
50 VI Steady state mass diffusion of gases and liquids through solid
51 VI General mass diffusion equation in Cartesian coordinates
52 VI Steady state equimolar counter diffusion
53 VI Isothermal evaporation of water through atmospheric air
54 VI Convective mass transfer: Evaluation of mass transfer coefficient
55 VI Problems using empirical relations available in data book
56 VI Analogy between momentum, heat and mass transfer
4.3 MODULE WISE SAMPLE QUESTIONS
MODULE 1
1. How does the science of Heat Transfer differ from the science of Thermodynamics? 2. What is heat flux? How is it related to the heat transfer rate? 3. Explain conduction shape factor and what is its significance 4. Starting with an energy balance on a cylindrical shell volume element, derive the
steady three-dimensional heat conduction equation for a long cylinder with constant thermal conductivity in which heat is generated at a rate of qg.
5. Starting with an energy balance on a rectangular volume element, derive the one-dimensional heat conduction equation for a plane wall with constant thermal conductivity and no heat generation.
6. Starting with an energy balance on a spherical shell volume element, derive the one-dimensional heat conduction equation for a sphere with constant thermal conductivity and no heat generation.
7. In a nuclear reactor, heat is generated uniformly in the 5 cm diameter cylindrical uranium rods at a rate of 7 x 107 W/m3. If the length of the rods is 1 m, determine the rate of heat generation in each rod.
8. Consider a large 3 cm-thick stainless steel plate in which heat is generated uniformly at a rate of 5 x 106 W/m3. Assuming the plate is losing heat from both sides, determine the heat flux on the surface of the plate during steady operation.
9. Consider a large 5 cm thick brass plate (k =111 W/m. °C) in which heat is generated uniformly at a rate of 2 x 105 W/m3. One side of the plate is insulated while the other side is exposed to an environment at 25°C with a heat transfer coefficient of 44 W/m2 °C. Explain where in the plate the highest and the lowest temperatures will occur, and determine their values.
10. A chemical reaction takes place in a cylinder (k= 0.6 W/m K) of inner radius 15mm
and outer radius 45mm. The inner surface is at 580OCand it is insulated. Assuming the
reaction rate of 0.55 MW/m3 in the reactor volume, find the temperature at the outer
surface of the reactor.
11. What is meant by logarithmic mean area and derive an expression for logarithmic
mean area for spheres.
12. Obtain an expression for the critical radius of insulation of a cylinder.
MODULE 2
1. Define Grashof number. Explain its significance in natural convection heat transfer.
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 19
2. Explain Reynold’s Analogy. What is its significance?
3. By dimensional analysis, establish the functional relationship between the relevant
non-dimensional numbers in the case of forced convection heat transfer.
4. Calculate the heat transfer from a 60W incandescent bulb at 115 0C to ambient air at
25 0C. Assume the bulb as a sphere of 50mm dia. Also find the percentage of power
lost by convection.
5. Define Prandtl number. Explain its significance.
6. Discuss the interrelationship between heat and momentum transfer. Write the
equation relating fluid friction and heat transfer.
7. Air at 300C is flowing across a tube with a velocity of 25 m/s. The tube should be either a cylinder of dia. 5cm or a square with a side of 5cm. Compare the rate of heat transfer in each case if the tube surface temperature is 1300C.
MODULE 3
1. Explain various regimes of saturated pool boiling.
2. Discuss the condensation process. Explain the different kinds of condensation process.
3. Derive the expressions for velocity distribution and mass flow rate of laminar film
condensation on a vertical plate.
4. How does transient heat transfer differ from steady heat transfer? 5. Consider a round potato being baked in an oven. Would you model the heat transfer to
the potato as one-, two-, or three-dimensional? Would the heat transfer be steady or transient?
6. Consider an egg being cooked in boiling water in a pan. Would you model the heat transfer to the egg as one, two, or three-dimensional? Would the heat transfer be steady or transient?
7. Define the terms Efficiency and Effectiveness of a fin. Develop a relation between them.
8. Derive an expression for the temperature distribution along an infinitely long fin
(rectangular) in dimensionless form under 1D steady state condition.
9. Derive an expression for the temperature distribution along a circular fin insulated at
the tip in dimensionless form under 1D steady state condition
MODULE 4
1. Draw the temperature profiles for counter flow and parallel flow heat exchangers when used as a condenser.
2. Derive an expression for the effectiveness of a parallel flow heat exchanger as a function of Number of Transfer Unit and Capacity Ratio.
3. Hot fluid enters on the shell side of a 2 - 4 heat exchanger (2 shell pass & 4 tube pass) at
750C and leaves at 390C while the cold fluid enters at 150C and leaves at 330C on the tube
side. Calculate the correction factor for this heat exchanger.
4. An oil cooler for a lubricating system has to cool 1000 kg/hr. of lubricating oil (Cp =
2.09kJ/K) from 800C to 400C by using a cooling water flow of 1000 kg/hr. at 300C. Give
your choice for a parallel flow or counter flow heat exchanger is suitable for this duty with
reasons. Calculate the surface area of the heat exchanger.
5. Water enters a Cross flow heat exchanger (both fluids unmixed) at 50C and flows at the
rate of 4600 kg/hr. to cool 4000 kg/hr. of air that is initially at 400C. Calculate the exit
temperatures of air and water if the surface area of the heat exchanger is 25 m2.
ME 302 HEAT AND MASS TRANSFER S6ME
COURSE HANDOUT: S6 Page 20
MODULE 5
1. Define Irradiation and Radiosity.
2. Explain the principle of working of a Radiation Shield. Give an expression for the total
resistance of heat exchange between two infinitely long parallel plates when two
shields are placed in between them.
3. Emissivities of two large parallel plates maintained at 8000C and 3000C are 0.3 and 0.5
respectively. Find the net radiant heat exchange per unit area for these plates. Find the
percentage reduction in heat transfer when a polished aluminum radiation shield of
emissivity 0.05 is placed between them.
4. A long steel rod 2cm dia. is to be heated from 4250C to 5500C. It is placed concentrically in a long cylindrical furnace which has an inside dia. of 15cm. The inner surface of the furnace is at a temperature of 10000C and has an emissivity of 0.85. If the emissivity of the rod is 0.6 find the time required for the heating operation. Take density of steel, ρ = 7845 kg/m3 and specific heat, cp = 0.67 kJ/ kg.K.
5. State and prove the Kirchhoff’s law of thermal radiation
6. Define the terms (i)Absorptivity, (ii) Reflectivity and (iii) Transmissivity
7. What is black body? Explain the reasons for considering a large cavity with a small
hole as a black body.
8. Discuss the procedure of setting up the electrical network analogy for thermal
radiation systems and find an expression for gray body factor.
9. Determine heat lost by radiation per meter length of 80mm dia. pipe (ε = 0.74) at
3000C, if:
a. Located in a large room with concrete walls at a temperature of 270C
b. Enclosed in a 160mm dia. concrete conduit at a temperature of 270C
MODULE 6
1. Explain the significance of Schmidt and Lewis Number. 2. What are the different modes of mass transfer, give one examples for each 3. State Fick’s law of diffusion. What do you understand by diffusion coefficient? Give its
unit. 4. An open pan 15cm in diameter and 30cm deep is filled with water at a level of 15cm
and is exposed to atmospheric air at 30% relative humidity. The entire system is at 600C. Calculate the evaporation rate of water and the time required for all water to evaporate.
5. Derive the general mass transfer equation in Cartesian coordinates 6. Define Mass flux and Molar flux 7. Discuss the analogy between heat and mass transfer. 8. Derive an expression for isothermal evaporation of water into air.
Prepared by Approved by
Mr. James Mathew Dr. Thankachan T Pullan
(Faculty) (HOD)
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 21
5. ME 304 DYNAMICS OF MACHINERY
5.1 COURSE INFORMATION SHEET
PROGRAMME: MECHANICAL
ENGINEERING
DEGREE: BTECH
UNIVERSITY:KTU
COURSE: DYNAMICS OF MACHINERY SEMESTER: 6 CREDITS: 3
COURSE CODE: ME 304
REGULATION: 2016
COURSE TYPE: CORE
COURSE AREA/DOMAIN:
APPLIED MECHANICS
CONTACT HOURS: 3+1 (Tutorial)
Hours/Week.
CORRESPONDING LAB COURSE CODE (IF
ANY): NIL
LAB COURSE NAME: NA
SYLLABUS: UNIT DETAILS HOURS
I Introduction to force analysis in mechanisms - static force analysis (four bar
linkages only) - graphical methods
Matrix methods - method of virtual work - analysis with sliding and pin friction
7
II Dynamic force analysis: Inertia force and inertia torque. D’Alemberts principle,
analysis of mechanisms (four bar linkages only), equivalent dynamical systems
Force Analysis of spur- helical - bevel and worm gearing
7
III Flywheel analysis - balancing - static and dynamic balancing - balancing of
masses rotating in several planes
Balancing of reciprocating masses - balancing of multi-cylinder in line engines -
V engines - balancing of machines
7
IV Gyroscope – gyroscopic couples
Gyroscopic action on vehicles-two wheelers, four wheelers, air planes and ships.
Stability of an automobile – stability of a two wheel vehicle –Stabilization of
ship.
7
V Introduction to vibrations – free vibrations of single degree freedom systems –
energy Method
Undamped and damped free vibrations – viscous damping – critical damping -
logarithmic decrement - Coulomb damping – harmonically excited vibrations
Response of an undamped and damped system – beat phenomenon -
transmissibility
7
VI Whirling of shafts – critical speed - free torsional vibrations – self excitation and
stability analysis - vibration control - vibration isolation – vibration absorbers
Introduction to multi-degree freedom systems - vibration measurement -
accelerometer – seismometer – vibration exciters
7
TOTAL HOURS 42
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 22
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
T1 Ballaney P.L. Theory of Machines, Khanna Publishers,1994
T2 S .S Rattan Theory of Machines, 3rd ed., Tata McGraw Hill Education Private Limited, Delhi, 2009.
T3 V. P. Singh, Theory of Machines, Dhanpat Rai,2013
R1 J. E. Shigley, J. J. Uicker, Theory of Machines and Mechanisms, McGraw Hill.
R2 H. Myskza, Machines and Mechanisms Applied Kinematic Analysis, Pearson Education,
4e, 2012
R3 A. Ghosh, A. K. Malik, Theory of Mechanisms and Machines, Affiliated East West Press.
R4 C. E. Wilson, P. Sadler, Kinematics and Dynamics of Machinery, 3rd edition, Pearson Education.. G. Erdman, G. N. Sandor, Mechanism Design: Analysis and synthesis Vol I & II,Prentice Hall of India
R5 Holowenko, Dynamics of Machinery, John Wiley R6 W.T.Thompson, Theory of vibration, Prentice Hall,1997
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
BE 100 ENGINEERING MECHANICS To have basic knowledge in
statics, dynamics, force analysis. 1
MA 102 DIFFERENTIAL EQUATIONS Knowledge in partial differential
equations 2
ME 301 MECHANICS OF MACHINERY
Basic knowledge in velocity and
acceleration analysis of
mechanism.
5
COURSE OBJECTIVES:
1 To impart knowledge on force analysis of machinery, balancing of rotating and
reciprocating masses, Gyroscopes, Energy fluctuation in Machines.
2 To introduce the fundamentals in vibration, vibration analysis of single degree of
freedom systems
3 To understand the physical significance and design of vibration systems with desired
Conditions
COURSE OUTCOMES:
SNO DESCRIPTION Bloom’s
Taxonomy
Level
CME 304.1
Students are capable of solving problems related to static and
dynamic force analysis of planar mechanism both graphically
and analytically and to analyze forces and their components
involved during the power transmission through spur, helical and
worm gears.
IV- Analyze
CME 304.2 Students can explain turning moment diagrams of IC engines and
can conduct flywheel analysis. Students are also capable of explaining how balancing of rotating and reciprocating
IV-Analyze
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 23
masses are done and can calculate the unbalanced forces and couples in a system.
CME 304.3 Students can explain the theory behind gyroscopic couple and to
predict the effect of gyroscopic couple in aircraft, ships and
automobiles.
III- Apply
CME 304.4 Knowledge in the vibration model of a system, concept of free damped and un damped, forced vibration systems and can solve problem related to different damping conditions.
III- Apply
CME 304.5
Students are capable of writing equation of motion of two degree, multi degree of freedom systems and choosing methods to solve frequency of such systems at different modes of vibration. Students have knowledge in the critical speed of shafts and are capable of solving problems related to free torsional vibrations in shafts. They also have knowledge in vibration absorbers, dampers and vibration measuring instruments.
III- Apply
CO-PO AND CO-PSO MAPPING:
PO 1
PO 2
PO 3
PO 4
PO 5
PO 6
PO 7
PO 8
PO 9
PO 10
PO 11
PO
12
PSO 1
PSO 2
PSO 3
CME304.1 3 2 - - - - - - - - - -
- 2 -
CME304.2 3 2 - - - - - - - - - -
- 2 -
CME304.3 3 - - - - - - - - - - -
- 2 -
CME304.4 3 - - - - - - - - - - -
- - -
CME304.5 3 - - - - - - - - - - -
- - -
AVG. VALUE 3 2
2 -
JUSTIFICATIONS FOR CO-PO MAPPING: MAPPING LOW/MEDIUM/
HIGH JUSTIFICATION
CME304.1-PO1 H Students could apply their acquired knowledge to conduct force analysis (both
static and dynamic analysis) of mechanisms.
CME304.1-PO2 M Knowledge in force analysis helps students to formulate problems and comment
on the possible solutions.
CME304.2-PO1 H Students could apply their acquired knowledge to calculate unbalanced forces
and couples in IC Engines and are also able to apply their knowledge in the
design of fly wheel.
CME304.2-PO2 M Knowledge in flywheel analysis help students to design it according to the
parameters given.
CME304.3-PO1 H Students are capable of explaining the theory of gyroscopic couple and can
predict the effect of this couple in aircrafts, ships and automobiles.
CME304.4-PO1 H Students could apply their knowledge in solving problems to find frequency of
vibration for both damped and un damped free vibration and forced vibration
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 24
system.
CME304.5-PO1 H Students capable of writing equation of motion of two degree, multi degree of
freedom systems and choosing methods to solve frequency of such systems at
different modes of vibration and are also capable of solving problems related to
free torsional vibrations in shafts
JUSTIFICATIONS FOR CO-PSO MAPPING
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL
REQUIREMENTS:
SNO DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
1
Mechanical Governors, types, working principle,
forces acting on the system, their application in
industries
PPT and
Printed
notes
provided for
referring
PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC
TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN:
SINO: TOPIC RELEVENCE
TO PO\PSO
1 Mechanical Governors
WEB SOURCE REFERENCES:
1 Dynamic force analysis of mechanism- https://www.youtube.com/watch?v=fEdz91oWrts
2 Gyroscope- https://www.youtube.com/watch?v=cquvA_IpEsA
3 Balancing of rotating masses
https://www.youtube.com/watch?v=5tVHxX2QgIA
4 Balancing video of a rotating turbine impeller
https://www.youtube.com/watch?v=VKr5RZt6MQo
MAPPING LOW/MEDIUM/
HIGH
JUSTIFICATION
CME304.1-PSO2 M Students could apply their knowledge in the in the domain of applied
mechanics to analyze mechanisms.
CME304.2-PSO2 M Knowledge in force analysis helps students to balance a rotating and
reciprocating unbalanced system.
CME304.3-PSO2 M Students are capable of applying principle of gyroscopic couple while
designing such mechanism.
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 25
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☐ CHALK & TALK ☐ STUD. ASSIGNMENT ☐ WEB
RESOURCES
☐LCD/SMART
BOARDS
☐ STUD. SEMINARS ☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD. SEMINARS ☐ TESTS/MODEL
EXAMS
☐ UNIV.
EXAMINATION
☐ STUD. LAB
PRACTICES
☐ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐ CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☐ ASSESSMENT OF COURSE OUTCOMES (BY
FEEDBACK, ONCE)
☐ STUDENT FEEDBACK ON FACULTY
(ONCE)
☐ ASSESSMENT OF MINI/MAJOR PROJECTS
BY EXT. EXPERTS
☐ OTHERS
5.2 COURSE PLAN:
DAY MODULE TOPIC PLANNED
1 1 Static force analysis introduction
2 1 Problem- four bar mechanism static force analysis- graphical method
3 1 Problem- four bar mechanism static force analysis
4 1 Super position principle- problem discussion- 4 bar mechanism
5 1 Principle of virtual work- problem discussion
6 1 Friction in mechanism- sliding pair
7 1
Friction in mechanism- revolute pair- problem discussion- friction in slider
crank mechanism
8 1
Problem discussion- static force analysis of slider crank mechanism with
friction involved
9 2 Dynamic force analysis- introduction-D'Alembert's principle
10 2
Dynamic force analysis- equivalent offset inertia force- Problem discussion
continued
11 2 Force analysis of spur, helical and worm gears
12 2 Force analysis of spur, helical and worm gears
13 3 Balancing of rotating masses- introduction
14 3 Balancing of rotating masses- problem discussion
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 26
15 3 Balancing of rotating masses- problem
16 3 Balancing of reciprocating masses- introduction
17 3 Partial balancing of locomotive engines-hammer blow- problem discussion
18 3 Locomotive engines partial balancing problem discussion continued
19 3
Inline engine- balancing of primary and secondary force-imaginary crank
method.
20 3 Balancing of v engine
21 3 Balancing of v-engine - direct and reverse crank method
22 3
Balancing machines- static and dynamic force balancing machines, field
balancing.
23 4 Gyroscopic couple theory- Introduction
24 4 Gyroscopic effect in aeroplanes, ships
25 4 Gyroscopic effect in four wheelers
26 4 Gyroscopic effect in four wheelers
27 4 Gyroscopic effect in two wheelers
28 5
Free vibration in single degree of freedom systems-Newtons method ,
energy method and Rayleigh’s method for formulation of equation of
motion of SDOF systems.
29 5
Problems related to formulation of equation of motion of SDOF free
vibration system
30 5 Free damped vibration systems- critical damping condition
31 5 Over damped and under damped condition of SDOF free vibration systems
32 5 Logarithmic decrement- problem discussion
33 5 Forced harmonic vibration- magnification factor
34 5 Displacement transmissibility
35 5 beat phenomenon
36 5 Whirling of shaft- problem discussion
37 6 Torsional vibration- two rotor system- problem discussion
38 6 Torsional vibration- three rotor system- problem discussion
39 6 Vibration absorbers and isolators- types
40 6 Multi degree of freedom systems- introduction
41 6 Influence coefficients
42 6 vibration measuring instruments- vibrometer
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 27
5.3 MODULE WISE SAMPLE QUESTIONS
MODULE 1
1. Explain the principle of virtual work applied in a slider crank mechanism.
2. In a four-bar mechanism ABCD the crank AB 5 cm long makes 60° with fixed link AD.
Link Be = 7 cm, CD = 9 cm and AD = 10 cm. A force of 8 N at 73.5° acts on BC at a
distance of 4 cm from B. Determine the reactive torque on link AB
3. Explain the static equilibrium conditions of two forces, three forces, two forces and a
torque member.
4. In a four-bar mechanism ABCD the crank AB = 5 cm long makes 60° with fixed link
AD. Link BC = 7 cm, CD = 9 cm and AD = 10 cm. A force of 8 N at 73.5° acts on BC at
a distance of 4 cm from B. Determine the reactive torque to be applied on link AB so that
the system is in static equilibrium.
5. Explain with an example the static force analysis of a slider crank mechanism in which
friction is considered for sliding and revolute pairs.
6. In a four- link mechanism shown in the figure below, torque T3 and T4 have magnitudes
of 30 Nm and 20 Nm respectively. The link lengths are AD= 800mm, AB= 300mm, BC=
700mm and CD= 400mm. For the static equilibrium of the mechanism, determine the
required input torque T2.
7. Find the torque required to be applied to link AB of the linkage shown in figure to
maintain static equilibrium. The force F is perpendicular to link CD acting at E. The
dimensions of the links are in mm.
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 28
MODULE 2
1. Explain equivalent offset inertia force in plane motions.
2. Explain a dynamically equivalent system. What are the conditions it should satisfy?
3. Find the magnitude and direction of inertia force acting on links AB, BC, CD, in the four
bar mechanism shown in Fig: 1
AB= 500 mm, BC= 660 mm, CD= 560 mm, AD= 1000 mm (horizontal),
ωAB = 10.5 rad/sec (CCW), angular retardation αAB= 26 rad/sec2
, ˂ DAB= 600
Mass of link AB, MAB = 3.54 kg, MBC = MCD = 3.54 kg /m length. Centre of gravity
link AB lies at 200 mm from A and has a moment of inertia of 88500 kg mm2. For link 3
& 4 Centre of gravity is at its mid point.
4. Find the equivalent offset inertia distance at which the inertia force are acting on the
links AB, BC, and CD of the mechanism shown in Fig 1. With a neat sketch represent
equivalent offset inertia forces acting on each link
MODULE 3
1. Explain static and dynamic balancing.
2. Derive an expression for maximum swaying couple.
3. With a neat sketch briefly describe the working of cradle type balancing machine.
4. Explain hammer blow and variation of tractive force.
5. Four masses A, B, C, D are completely balanced. Masses C & D make angles of 900 and
1950 respectively with that of mass B in CCW direction. The rotating mass have
following properties:-
mB =25 kg, mC = 40kg, mD = 35 kg
rA= 150 mm, rB = 200 mm, rC = 100 mm, rD = 180 mm.
Planes B and C are 250mm apart.
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 29
Find: (1) mass A and its angular position with that of mass B.
(2) Positions of all the planes relative to the plane of mass A
6. The following data refers to a two cylinder uncoupled locomotive engine:
Rotating mass per cylinder = 280 kg
Reciprocating mass per cylinder= 300 kg
Distance between wheels= 1400mm
Distance between cylinder centers= 600 mm
Angular velocity of balancing mass= 15.43 rad/sec
Crank radius= 300 mm
Radius of centre of balancing mass= 620 mm
Angle between cylinder cranks= 90 deg
Dead load on each wheel= 3.5 tonne
Find: a) Balancing mass required in the planes of driving wheels if whole of the
revolving and 2/3 rd
of the reciprocating mass are to be balanced
b) Swaying couple
c) Tractive force
d) Maximum and minimum pressure on the rails
7. Derive the expression for coefficient of fluctuation of energy.
8. Explain the turning moment diagram of a single cylinder four stroke engine with a neat
sketch.
9. Determine the energy released by the flywheel having a mass of 2 kN and radius of
gyration of 1.2 m when the speed decreases from 460 rpm to 435 rpm.
10. Explain and derive an expression for a) Piston effort b) Force along the connecting rod c)
Thrust on the sides of the cylinder d) Crank effort e) Thrust on the bearings.
11. A flywheel fitted to a steam engine has a mass of 800 kg. Its radius of gyration is 360
mm. The starting torque of the engine is 580 Nm and may be assumed constant. Find the
kinetic energy of the flywheel after 12 seconds.
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 30
MODULE 4
1. Each wheel of a four wheeled, rear engine automobile has a moment of inertia of
2.4kgm2 and an effective diameter of 660 mm. The rotating parts of the engine have a
moment of inertia of 1.2kgm2. The gear ratio of the engine to the back wheel is 3 to 1.
The engine axis is parallel to the rear axle and the crank shaft rotates in the same sense as
the road wheels. The mass of the vehicle is 2200 kg and the center of the mass is 550
mm above the road level. The track width of the vehicle is 1.5 m. Determine the limiting
speed of the vehicle around a curve with 80 m radius so that all the four wheels maintain
contact with the road surface.
2. Derive the expression for gyroscopic couple.
3. Explain the stability of two wheel vehicles while taking a curve.
4. Explain the gyroscopic effect on sea vessels
5. A uniform disc of 50 kg mass and 800 mm diameter is mounted on a shaft. The plane of
the disc is not perfectly at right angles to the axis of the shaft but has an error of 1.5
degree. Determine the gyroscopic couple acting on the bearing if the shaft rotates at 840
rpm.
6. Derive an expression for gyroscopic couple on a rigid disc at an angle fixed to a rotating
shaft.
7. The rotor of the turbine of a ship has a mass of 2500kg and rotates at a speed of 3200
rpm CW, when viewed from stern. The rotor has radius of gyration of 0.4 m. Find
gyroscopic couple and its effects on the ship when:
I. The ship steers to the left in a curve of 80 m radius at a speed of 7.75 m/s
II. The ship pitches 5 degrees above and 5 degree below the normal position and the
bow descending with its maximum velocity- the pitching motion is simple
harmonic with a time period of 40 seconds
III. The ship rolls at an angular velocity of 0.4 m/s CW when viewed from stern
MODULE 5
1. Derive an expression for energy dissipated per cycle in single degree of freedom system
with viscous damping.
2. Find the expression of frequency of free vibration of the system shown in figure 1.
Assume the chord passing over the frictionless pulley is inextensible.
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 31
3. A vibrating system is defined by the following parameters:
m= 3 kg, k= 100 N/m, C=3 N- sec/m
Determine: a) damping factor, b) the natural frequency of damped vibration,
c) Logarithmic decrement, d) the ratio of two consecutive amplitudes and
e) The number of cycles after which the original amplitude is reduced to 20 percent.
MODULE 6
1. Difference between vibration absorbers and vibration isolators.
2. Explain co-ordinate coupling.
3. Explain the working of unturned dry friction damper with a neat diagram.
4. Derive an expression for displacement transmissibility of a spring mass damper system
subjected to a force.
5. Explain two types of frequency measuring instruments
6. A machine weighing 1600 kg is mounted on a spring having stiffness of 10800 N/cm. A
piston within the machine weighing 25 N has a reciprocating motion with a stroke of 7.5
cm and a speed of 6000 rpm. Assume the motion to be simple harmonic. Determine: a)
Amplitude of vibration of machine. b) Transmissibility and force transmitted to the
ground. Take = 0.2
7. A single cylinder vertical petrol engine of total mass 320 kg is mounted upon a steel
chassis and causes a vertical static deflection of 2 mm. The reciprocating parts of the
engine have a mass of 24kg and move through a vertical stroke of 150mm. with simple
harmonic motion. A dashpot attached to the system offers a resistance of 490 N at a
velocity of 0.3 m/sec. Determine:
a) The speed of the driving shaft at resonance
b) The amplitude of steady state vibration when the driving shaft of the engine rotates at
480 rpm.
8. A centrifugal pump rotating at 600 r.p,m. is driven by an electric motor running at 1500
r.p.m through a single stage reduction gearing. The moment of inertia of the pump
impeller and the motor are 150 Kg-m2 and 450 Kg-m
2 respectively. The lengths of the
pump shaft and the motor shafts are 500 mm and 300 mm, and their diameters are 100
mm and 60 mm respectively. Neglecting the inertia of the gears, find the frequency of
torsional oscillations of the system, and draw the mode shape. Take G = 82 GPa.
9. Find the natural frequencies for the torsional system shown in figure below:
Given J1= J0, J2 = 2J0 and kt1= kt2 = kt3 = kt
ME 304 DYNAMICS OF MACHINERY S5ME
COURSE HANDOUT: S6 Page 32
10. Describe critical speed of shaft.
11. The rotor of a turbo charger weighing 90 N is keyed to the centre of 25 mm diameter
steel shaft 40 cm between bearings. Determine:
a) Critical speed of shaft
b) The amplitude of vibration of rotor at a speed of 3200 rpm, if the eccentricity is
0.015 mm
c) Dynamic force transmitted to the bearing at this speed. Take density of shaft material
as 8 gm/cm3, E= 200 GPa.
Prepared by Approved by
Mr. Senjo Manuel Dr.Thankachan T Pullan
(Faculty) (HOD)
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 33
6. ME306 ADVANCED MANUFACTURING TECHNOLOGY
6.1 COURSE INFORMATION SHEET
PROGRAMME: ME DEGREE: BTECH
COURSE: ADVANCED
MANUFACTURING TECHNOLOGY
SEMESTER: 6 CREDITS: 3
COURSE CODE: ME306
REGULATION: 2016
COURSE TYPE: CORE
COURSE AREA/DOMAIN: PRODUCTION
& INDUSTRIAL ENGINEERING
CONTACT HOURS: 3 Lectures/Week.
CORRESPONDING LAB COURSE CODE
(IF ANY): NIL
LAB COURSE NAME: NA
SYLLABUS: UNIT DETAILS HOURS
I Introduction: Need and comparison between traditional, non-traditional and micro & nano machining process. Powder Metallurgy: Need of P/M - Powder Production methods:- Atomization, electrolysıs, Reduction of oxides, Carbonyls (Process parameters, characteristics of powder produced in each method). Powder characteristics: properties of fine powder, size, size distribution, shape, compressibility, purity etc. Mixing – Compaction:- techniques, pressure distribution, HIP & CIP. Mechanism of sintering, driving force for pore shirking, solid and liquid phase sintering - Impregnation and Infiltration Advantages, disadvantages and specific applications of P/M. Programmable Logic Controllers (PLC): need – relays - logic ladder program –timers, simple problems only. Point to point, straight cut and contouring positioning - incremental and absolute systems – open loop and closed loop systems - control loops in contouring systems: principle of operation.
7
II DDA integrator:-Principle of operation, exponential deceleration –liner, circular and complete interpolator. NC part programming: part programming fundamentals - manual programming – NC coordinate systems and axes –– sequence number, preparatory functions, dimension words, speed word, feed world, tool world, miscellaneous functions – Computer aided part programming:– CNC languages – APT language structure: geometry commands, motion commands, postprocessor commands, compilation control commands Programming exercises: simple problems on turning and drilling etc - machining centers- 5 axis machining
7
III Electric Discharge Machining (EDM):- Mechanism of metal removal, dielectric fluid, spark generation, recast layer and attributes of process characteristics on MRR, accuracy, HAZ etc, Wire EDM, applications and accessories. Ultrasonic Machining (USM):-mechanics of cutting, effects of
6
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 34
parameters on amplitude, frequency of vibration, grain diameter, slurry, tool material attributes and hardness of work material, applications. Electro chemical machining (ECM):- Mechanism of metal removal attributes of process characteristics on MRR, accuracy, surface roughness etc, application and limitations.
IV Laser Beam Machining (LBM), Electron Beam Machining (EBM), Plasma arc Machining (PAM), Ion beam Machining(IBM) - Mechanism of metal removal, attributes of process characteristics on MRR, accuracy etc and structure of HAZ compared with conventional process; application, comparative study of advantages and limitations of each process. Abrasive Jet Machining (AJM), Abrasive Water Jet Machining (AWJM) - Working principle, Mechanism of metal removal, Influence of process parameters, Applications, Advantages & disadvantages.
6
V High velocity forming of metals:-effects of high speeds on the stress strain relationship steel, aluminum, Copper – comparison of conventional and high velocity forming methods- deformation velocity, material behavior, strain distribution. Stress waves and deformation in solids – types of elastic body waves- relation at free boundaries- relative particle velocity. Sheet metal forming: - explosive forming:-process variable, properties of explosively formed parts, etc. Electro hydraulic forming: - theory, process variables, etc, comparison with explosive forming.
8
VI Micromachining: Diamond turn mechanism, material removal mechanism, applications. Advanced finishing processes: - Abrasive Flow Machining, Magnetic Abrasive Finishing. Magnetorheological Abrasive Flow Finishing, Magnetic Float Polishing, Elastic Emission Machining. Material addition process:- stereo-lithography, selective laser sintering, 3D Printing, fused deposition modeling, laminated object manufacturing, , laser engineered net-shaping, laser welding, LIGA process.
8
TOTAL HOURS 42
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
T1 M.P. Groover, E.M. Zimmers, Jr. CAD/CAM; Computer Aided Design and Manufacturing,
Prentice Hall of India, 1987 T2 Davies K and Austin E.R, Developments in high speed metal forming, the machinery
publishing Co, 1970.
R1 ASTME, High velocity forming of metals, PHI, 1968.
R2 Ibrahim Zeid, R Sivasubrahmanian CAD/CAM: Theory & Practice, McGraw Hill
Education, 2009
R3 Jain V.K., Introduction to Micromachining, Narosa publishers,2014
R4 Petruzella Frank.D., Programmable logic controllers,McGraw Hill,2016
R5 Yoram Koren, Computer control of manufacturing systems, TMH,2006
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
ME220 Manufacturing Technology To have knowledge in basic
manufacturing processes 4
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 35
BE 101-02 Introduction to Mechanical
Engineering Sciences
Preliminary Knowledge about
various Mechanical
Manufacturing methods.
1
- Mathematics Basic knowledge in mathematical
calculations
School
Level
COURSE OBJECTIVES:
1 To introduce machining principles and processes in the manufacturing of precision components and products that use conventional and nonconventional technologies
2 To give basic understanding of the machining capabilities, limitations, and productivity of advanced manufacturing processes.
3 To describe how PLC’s operate and how they control automated equipment and systems
4 To demonstrate tool path simulations with CNC powered equipment
5 To introduce CNC programming
COURSE OUTCOMES:
SL.NO DESCRIPTION Bloom’s
Taxonomy
Level
CME306.1 Students will be able to understand the powder metallurgy process and steps involved in the process.
Understand
(Level 2)
CME306.2
Students will be able to gain knowledge on fundamentals of NC part programming methods and computer aided part programming and also can apply these programs to perform on a CNC machine tool.
Apply
(Level 3)
CME306.3 Students will have the ability to understand the different processes like EDM, ECM and USM.
Understand
(Level 2)
CME306.4
Students will be able to recommend appropriate machining process from LBM, EBM, AWM, AWJM processes for different applications after gaining knowledge about the above processes.
Evaluate
(Level 5)
CME306.5 Students will be able to gain fundamental knowledge in micromachining and material addition process.
Knowledge
(Level 1)
CO-PO AND CO-PSO MAPPING PO
1 PO 2
PO 3
PO 4
PO 5
PO 6
PO 7
PO 8
PO 9
PO 10
PO 11
PO 12
PSO 1
PSO 2
PSO 3
CME306.
1 2 2 - - - - - - - - - - - 3 -
CME306.
2 3 2 - - 3 - - - - - - 3 - 3
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 36
CME306.
3 2 2 - - 2 - - - - - - - - 3 -
CME306.
4 2 2 - - 2 - - - - 2 - 2 - 3 -
CME306.
5 2 - - - 3 - - - - - - 2 - 3 -
CME306 1.8 2 - - 2.5 - - - - 2 - 2.3 - 3 3
JUSTIFICATIONS FOR CO-PO MAPPING MAPPING LOW/MEDIUM/
HIGH JUSTIFICATION
CME306.1-
PO1 M
Acquire the knowledge of the science behind between
different advanced manufacturing methods
CME306.1-
PO2 M
Students will get the ability to analyse the different steps
involved in the powder metallurgical processes
CME306.2-
PO1 H
Knowledge in part programming will enable students to
work out different machining operations in CNC
machine which are difficult to carry out by conventional
machining.
CME306.2-
PO2 M
Knowledge in programming codes that are used in NC
part programming and computer aided part
programming will enable the students analyse different
programs that are being used in CNC machines.
CME306.2-
PO5 H
CNC considered to be one of the modern machine used
in industries to carry out machining operations like
turning, milling, etc so accurately. Students will be able
to apply the engineering knowledge that they got in part
programming in CNC machines.
CME306.2-
PO12 H
Students will be able to analyse the different codes used
in part programming so that they can develop effective
programs that will be useful for CNC machines.
CME306.3-
PO1 M
Students will be gain knowledge in the processes like
EDM, ECM, and USM.
CME306.3-
PO2 M
Students will get to know the different parameters of
EDM, ECM, and USM.
CME306.3-
PO5 M
After gaining sufficient knowledge about EDM, ECM,
USM, students will be able to select appropriate method
for the machining of different engineering materials.
CME306.4-
PO1 M
Students will be able to understand the mechanism of
material removal of each non-conventional machining
process by acquiring knowledge about each processes.
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 37
CME306.4-
PO2 M
By identifying the importance of entities of each non-
traditional machining processes, the students will be
able to apply these processes for specific applications.
CME306.4-
PO5 M
Knowledge in different advanced manufacturing
processes like LBM, EBM, AWM, AWJM will enable
students to choose the appropriate method for required
application.
CME306.4-
PO10 M
Students after getting knowledge about different
machining processes will be able to communicate to the
society about the right process for the right application.
CME306.4-
PO12 M
Knowledge about the technological changes which may
occur by modifying the parameters of non-conventional
process will keep students’ interest on working with
modifications of these processes.
CME306.5-
PO1 M
Ability to understand different material addition and
micromachining processes will enable the students to
identify the changes that may occur in future to each of
the methods.
CME306.5-
PO5 H
Knowledge about the recent innovations in printing like
3D printing and other material addition and
micromachining processes will enable students to use
modern tools for learning activities.
CME306.5-
PO12 M
New methods of material addition processes based upon
the technological changes will help the students to think
about the innovations that can happen in the printing
technology.
JUSTIFICATIONS FOR CO-PSO MAPPING
MAPPING LOW/MEDIUM/
HIGH
JUSTIFICATION
CME306.1-
PSO2 H
Understanding of powder metallurgy process will
enable students to know about the different
applications at which the process is being used.
CME306.2-
PSO3 H
Ability to write part programs and computer aided
part programs for modern CNC machines will help the
students to be in touch with the industries which are
using modern technology.
CME306.3-
PSO2 H
Studies on non-conventional processes like EDM, ECM
and USM will be useful for students to identify its
importance in manufacturing scenario.
CME306.4- H Ability to analyse different entities involved in non-
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 38
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL
REQUIREMENTS:
SNO DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
1
Study on process parameters and capabilities of
advanced finishing and material addition
processes
PO2, PO12,
PSO2
NPTEL +
Reading
books
TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN:
SINO: TOPIC RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
1 Hybrid approaches in non-conventional
processes
PO2, PO12, PSO2 Reading
Journal papers
2 Environmental friendly manufacturing
processes
PO7, PO6 Seminar
presentations
WEB SOURCE REFERENCES:
1 http://nptel.ac.in/courses/112105127/
2 http://home.iitk.ac.in/~jrkumar/
3 http://nptel.ac.in/courses/112105126/
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☐CHALK &
TALK
☐ STUD.
ASSIGNMENT
☐ WEB
RESOURCES
☐LCD/SMART
BOARDS
☐ STUD.
SEMINARS
☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD.
SEMINARS
☐ TESTS/MODEL
EXAMS
☐ UNIV.
EXAMINATION
PSO2 conventional processes like AJM, AWJM, and beam
machining methods will make the students to choose
the appropriate method that is applicable to a
particular situation.
CME306.5-
PSO2 H
Students will be able to understand about the
material addition processes and micromachining
processes and will implement in their learning
activities to develop such kind of technology like 3D
printing.
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 39
☐ STUD. LAB
PRACTICES
☐ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐
CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☐ ASSESSMENT OF COURSE OUTCOMES
(BY FEEDBACK, ONCE)
☐ STUDENT FEEDBACK ON
FACULTY (ONCE)
☐ ASSESSMENT OF MINI/MAJOR
PROJECTS BY EXT. EXPERTS
☐ OTHERS
6.2 COURSE PLAN
DAY MODULE TOPIC PLANNED
1 I Introduction: Need and comparison between traditional, non-traditional and micro & nano machining process.
2 I Powder Metallurgy: Need of P/M - Powder Production methods:- Atomization, electrolysıs
3 I Reduction of oxides, Carbonyls (Process parameters, characteristics of powder produced)
4 I Powder characteristics: properties of fine powder, size, size distribution, shape, compressibility, purity etc.
5 I Mixing – Compaction:- techniques, pressure distribution, HIP & CIP.
6 I Mechanism of sintering, driving force for pore shirking, solid and liquid phase sintering
7 I Impregnation and Infiltration Advantages, disadvantages and specific applications of P/M.
8 I Programmable Logic Controllers (PLC): need – relays - logic ladder program –timers, simple problems only.
9 I Point to point, straight cut and contouring positioning - incremental and absolute system
10 I Open loop and closed loop systems - control loops in contouring systems: principle of operation.
11 II DDA integrator:-Principle of operation, exponential deceleration –liner, circular and complete interpolator.
12 II NC part programming: part programming fundamentals - manual programming
13 II NC coordinate systems and axes –– sequence number, preparatory functions, dimension words, speed word, feed world, tool world, miscellaneous functions
14 II Computer aided part programming:– CNC languages – APT language structure: geometry commands, motion commands
15 II Postprocessor commands, compilation control commands
16 II Programming exercises: simple problems on turning and drilling etc - machining centers- 5 axis machining
17 III Electric Discharge Machining (EDM):- Mechanism of metal removal
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 40
18 III Dielectric fluid, spark generation, recast layer
19 III Attributes of process characteristics on MRR, accuracy, HAZ etc, Wire EDM, applications and accessories.
20 III Ultrasonic Machining (USM):-mechanics of cutting, effects of parameters on amplitude, frequency of vibration, grain diameter, slurry
21 III Tool material attributes and hardness of work material, applications
22 III Electro chemical machining (ECM):- Mechanism of metal removal attributes of process characteristics on MRR, accuracy, surface roughness etc, application and limitations
23 IV Laser Beam Machining (LBM) Mechanism of metal removal, attributes of process characteristics on MRR, accuracy etc
24 IV Electron Beam Machining (EBM), Mechanism of metal removal, attributes of process characteristics on MRR, accuracy etc
25 IV Plasma arc Machining (PAM), Mechanism of metal removal, attributes of process characteristics on MRR, accuracy etc
26 IV Ion beam Machining(IBM) Mechanism of metal removal, attributes of process characteristics on MRR, accuracy etc
27 IV Structure of HAZ compared with conventional process; application, comparative study of advantages and limitations of each process
28 IV Abrasive Jet Machining (AJM), Working principle, Mechanism of metal removal, Influence of process parameters, Applications, Advantages & disadvantages.
29 IV Abrasive Water Jet Machining (AWJM) Working principle, Mechanism of metal removal, Influence of process parameters, Applications, Advantages & disadvantages.
30 V High velocity forming of metals:-effects of high speeds on the stress strain relationship- steel, aluminum, Copper
31 V Comparison of conventional and high velocity forming methods
32 V Deformation velocity, material behavior, strain distribution.
33 V Stress waves and deformation in solids
34 V Types of elastic body waves- relation at free boundaries- relative particle velocity
35 V Sheet metal forming: - explosive forming
36 V Process variable, properties of explosively formed parts, etc.
37 V Electro hydraulic forming: - theory, process variables, etc, comparison with explosive forming.
38 VI Micromachining: Diamond turn mechanism, material removal mechanism, applications.
39 VI Advanced finishing processes: - Abrasive Flow Machining
40 VI Magnetic Abrasive Finishing
41 VI Magnetorheological Abrasive Flow Finishing
42 VI Magnetic Float Polishing
43 VI Elastic Emission Machining
44 VI Material addition process:- stereo-lithography, selective laser sintering, 3D Printing, fused deposition modeling
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 41
45 VI laminated object manufacturing, , laser engineered net-shaping, laser welding, LIGA process
6.3 MODULE WISE SAMPLE QUESTIONS
Module 1
1. Explain powder metallurgy process
2. With neat sketches explain the methods used to produce metallic powders in powder
metallurgy
3. Explain different steps involved in powder metallurgy
4. Write a detailed note on PLC
5. What is meant by interpolation in NC systems? Explain different types of interpolations.
Module 2
1. Write a detailed note on DDA integrator
2. Mention the purpose of miscellaneous functions in part programming.
3. Explain about the different commands used in APT program
4. Define any 5 G codes and M codes
5. Write a sample part program for turning operation and explain about each codes used in
program.
Module 3
1. What are the functions and desirable properties of dielectric fluid in EDM?
2. Explain desirable properties of electrode material electrode material used in EDM.
3. Explain about ECM process
4. Describe in detail the material removal mechanism of USM process.
5. How Micro EDM process is different from EDM process?
Module 4
1. Describe advantages and limitations of ion beam machining
2. Describe the mechanism of material removal in ion beam machining
3. What are the advantages and disadvantages of Laser beam machining process?
4. With a neat sketch explain Electron beam machining process
5. What are the advantages and disadvantages of AWJM? Describe the applications of
AWJM.
Module 5
1. Explain about high velocity forming methods
2. Write in detail the electrohydraulic forming process
3. How explosive forming process is different from other forming processes?
4. Write notes on effect of high speeds on stress strain relationship of metals
5. How sheet metals can be formed?
ME 306 ADVANCED MANUFACTURING TECHNOLOGY S6 ME
COURSE HANDOUT: S6 Page 42
Module 6
1. What is laminated object manufacturing? Explain the process with sketches.
2. What is LIGA process? Explain it with neat sketches.
3. With neat sketch explain Abrasive flow finishing process
4. Explain Magnetorheological abrasive flow finishing process with suitable diagram
5. With a neat sketch explain Selective laser sintering
6. Explain the working of laser engineered net shaping with sketch.
Prepared by Approved by
Mr. Jeffin Johnson Dr. Thankachan T Pullan
(Faculty, DME) (HOD, DME)
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 43
7. ME 308 COMPUTER AIDED DESIN AND ANALYSIS
7.1 COURSE INFORMATION SHEET
PROGRAMME: MECHANICAL
ENGINEERING
DEGREE: B.TECH
COURSE: COMPUTER AIDED DESIN AND
ANALYSIS
SEMESTER: V CREDITS: 3
COURSE CODE: ME 308 REGULATION:
UG
COURSE TYPE: CORE
COURSE AREA/DOMAIN: COMPUTER
AIDED DESIGNAND ENGINEERING.
CONTACT HOURS: 3 hours/Week.
CORRESPONDING LAB COURSE CODE
(IF ANY): ME 332
LAB COURSE NAME: COMPUTER AIDED
DESIGN AND ANALYSIS LAB
SYLLABUS:
UNIT DETAILS HOURS
I
Introduction to CAD , Historical developments, Industrial look at CAD,
Comparison of CAD with traditional designing, Application of computers in
Design
Basics of geometric and solid modeling, Packages for CAD/CAM/CAPP
Hardware in CAD components, user interaction devices, design database, graphic
Standards, data Exchange Formats, virtual Reality.
7
II
Transformation of points and line, 2-D rotation, reflection, scaling and combined
transformation, homogeneous coordinates, 3-D scaling.
Shearing, rotation, reflection and translation, combined transformations,
orthographic and perspective projections, reconstruction of 3-D objects.
7
III
Algebraic and geometric forms, tangents and normal, blending functions,
reparametrization, straight lines, conics, cubic splines, Bezier curves and B-spline
curves.
Plane surface, ruled surface, surface of revolution, tabulated cylinder, bi-cubic
surface, bezier surface, B-spline surfaces and their modeling techniques.
7
IV Solid models and representation scheme, boundary representation, constructive
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 44
solid geometry
Sweep representation, cell decomposition, spatial occupancy enumeration,
coordinate systems for solid modeling.
7
V
Introduction to finite element analysis - steps involved in FEM- Preprocessing
phase – discretization - types of elements
Formulation of stiffness matrix (direct method, 1-D element) - formulation of load
vector - assembly of global equations - implementation of boundary conditions -
solution procedure - post processing phase
Simple problems with axial bar element (structural problems only)
7
VI
Interpolation – selection of interpolation functions - CST element - isoparametric
formulation (using minimum PE theorem) – Gauss-quadrature
Solution of 2D plane stress solid mechanics problems (linear static analysis)
7
Total Hours 42
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
T M.P. Groover, E.M. Zimmers, Jr.CAD/CAM; Computer Aided Design and
Manufacturing, Prentice Hall of India, 1987
T T. R. Chandrupatla and A. D. Belagundu, Introduction to Finite Elements in
Engineering, Pearson Education, 2001
R Chris Mcmahon and Jimmie Browne - CAD/CAM – Principle Practice and
Manufacturing Management, Addision Wesley England,1998
R D. F. Rogers and J. A. Adams, Mathematical Elements in Computer Graphics,
McGraw-Hill,1990
R Daryl Logan, A First course in Finite Element Method, Thomson Learning,2007
R David V Hutton, Fundamentals of Finite Element Analysis, THM,2003
R Donald Hearn, M. Pauline Baker and Warren Carithers, Computer Graphics with open
GL, Pearson Education,2001
R Grigore Burdea, Philippe Coiffet, Virtual Reality Technology, John Wiley and
sons,2003
R Ibrahim Zeid, CAD/ CAM Theory and Practice, McGraw Hill,2007
R P. Radhakrishnan and S. Subramanyan, CAD / CAM / CIM, New Age Int. Ltd.,2008
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
ME 201 Mechanics of solids
Knowledge about various
Mechanical components. Analysing
free body diagrams.
III
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 45
COURSE OBJECTIVES:
1 To impart basic knowledge on Computer Aided Design methods and procedures
2 To introduce the fundamentals of solid modelling
3 To introduce the concepts of finite element analysis procedures
COURSE OUTCOMES:
SNO DESCRIPTION Bloom’s
Taxonomy
Level
CME308.1 Students able to express the concept of CAD/CAM/CIM and Other
terminologies used in the development and manufacturing of a
product.
Understand
(level2)
CME308.2 Students able to demonstrate different methods for geometric
modelling in CAD.
Appy
(level 3)
CME308.3 Students able to evaluate the types of curves used in creating a
geometry.
Analayse
(level 4 )
CME308.4 Students able to formulate stiffness matrix to analyse structural
and thermal problems
Create
(level 6)
CME308.5
Students analyse structural finite element problems by getting
knowledge about various finite element methods.
Analyse
(level 3)
CO-PO AND CO-PSO MAPPING
P
O
1
PO
2
P
O
3
P
O
4
P
O
5
P
O
6
P
O
7
P
O
8
P
O
9
P
O
10
P
O
11
P
O
12
PS
O
1
PS
O
2
PS
O
3
C 3 0 8 . 1 2 2 2 3
C 3 0 8 . 2 2 3
C 3 0 8 . 3 2 3
C 3 0 8 . 4 3 3 3
C 3 0 8 . 5 3 2 - 3 3
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 46
JUSTIFICATIONS FOR CO-PO MAPPING
MAPPING LOW/MEDIUM
/
HIGH
JUSTIFICATION
C308.1-PO5 M CAD /CAM modern tools for the design and manufacturing
environment.
C308.1-PO10 M Learns about how communication takes place in a
manufacturing environment
C308.1-PO11 M Knows the management tools used in Production
environment
C308.2-PO2 M Learns about Geometric transforms how it can be used for
modelling
C308.3-PO1 M Make use of types of curves to create geometries.
C308.3-PO2 H Become aware of the requirement curves to create
geometries
C308.4-PO1 H Analytical knowledge on the FEA helps the students to
solve of the engineering problems related to linear static and
structural analysis.
C308.4-PO2 H Analytical knowledge on the FEA helps the students to
solve of the engineering problems using finite element
method.
C308.5-PO1 H Ability to apply various mathematical formulations to wire
frame, surface and solid entities is useful for designing
efficient system components.
C308.5-PO2 M Knowledge on the computer aided design and analysis will
help the students to reduce design errors.
C308.5-PO12 H Ability to apply parametric equations in representation of
modelling entities helps the students to pursue higher
education in the fields like CAD/CAM/CIM. And lifelong
learning.
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 47
JUSTIFICATIONS FOR CO-PSO MAPPING
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL
REQUIREMENTS:
SNO DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN:
SNO DESCRIPTION RELEVENCE TO
PO\PSO
PROPOSED
ACTIONS
WEB SOURCE REFERENCES:
1 https://www.autodesk.in/solutions/cad-cam
2 https://en.wikipedia.org/wiki/Computer-aided_manufacturing
3 ttps://www.webopedia.com/TERM/C/CAD_CAM.html
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☑ CHALK & TALK ☑ STUD. ASSIGNMENT ☐ WEB
RESOURCES
☐LCD/SMART
BOARDS
☐ STUD.
SEMINARS
☐ ADD-ON COURSES
MAPPING LOW/MEDIUM/
HIGH
JUSTIFICATION
C308.1-PSO3 H Students can apply their knowledge in computer aided
design to reach design solutions for practical mechanical
design engineering problems.
C308.2- PSO3 H Design knowledge in wire frame/surface/solid modelling
techniques.
C308.4-PSO1 H Finite element analysis help to solve linear and static
analysis hence solve complex problems.
C308.5-PSO1 H Finite element analysis help to solve linear and static
analysis hence solve complex problems.
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 48
ASSESSMENT METHODOLOGIES-DIRECT
☑ASSIGNMENTS ☐ STUD.
SEMINARS
☑ TESTS/MODEL
EXAMS
☑UNIV.
EXAMINATION
☐ STUD. LAB
PRACTICES
☐ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐
CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☑ASSESSMENT OF COURSE OUTCOMES
(BY FEEDBACK, ONCE)
☑STUDENT FEEDBACK ON FACULTY
(TWICE)
☐ ASSESSMENT OF MINI/MAJOR
PROJECTS BY EXT. EXPERTS
☐ OTHERS
7.2 COURSE PLAN
DAY MODULE TOPIC PLANNED
1 1
Industrial look at CAD, Comparison of CAD with traditional designing,
Application of computers in Design
2 1
Basics of geometric and solid modeling, Packages for
CAD/CAM/CAE/CAPP
3 1 Hardware in CAD components,
4 1 user interaction devices, design database, graphic Standards
5 1 data Exchange Formats
6 1 virtual Reality.
7 2 Transformation of points and line,
8 2 2-D rotation, reflection, scaling
9 2 combined transformation,
10 2 homogeneous coordinates,
11 2 3-D scaling.
12 2 Shearing,rotation, reflection and translation
13 2 combined transformations, orthographic and perspective projections
14 2 reconstruction of 3-D objects
15 3 Algebraic and geometric forms, tangents and normal
16 3 blending functions, reparametrization
17 3 straight lines, conics, cubic splines
18 3 Bezier curves and B-spline curves.
19 3 Plane surface, ruled surface
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 49
20 3 surface of revolution, tabulated cylinder
21 3
bi-cubic surface, bezier surface, B-spline surfaces and their modeling
techniques.
22 4 Solid models and representation scheme
23 4 boundary representation
24 4 constructive solid geometry.
25 4 Sweep representation
26 4 cell decomposition
27 4 spatial occupancy enumeration
28 4 coordinate systems for solid modeling
29 5 Introduction to finite element analysis
30 5
steps involved in FEM- Preprocessing phase – discretisation - types of
elements
31 5
Formulation of stiffness matrix (direct method, 1-D element) - formulation
of load vector
32 5 solution procedure - post processing phase
33 5 Simple problems with axial bar element (structural problems only
34 6 Interpolation – selection of interpolation functions
35 6 Interpolation – selection of interpolation functions
36 6 CST element - isoparimetric formulation (using minimum PE theorem)
37 6 Gauss-quadrature
38 6
Solution of 2D plane stress solid mechanics problems (linear static
analysis)
39 6
Solution of 2D plane stress solid mechanics problems (linear static
analysis)
40 6 solution procedure - post processing phase
41 6 Simple problems with axial bar element (structural problems only
42 6 Interpolation – selection of interpolation functions
43 6 Interpolation – selection of interpolation functions
7.3 MODULE WISE SAMPLE QUESTIONS
UNIT-I
1. Explain the components of CAD system.
2. Difference between Conventional Design & Computer aided Design.
3. Explain Working and importance of Raster Display.
4. Differentiate Raster scan and random scan dislay system
5. Rasterize a quarter circle using Bresenhams midpoint algorithm in positive quadrant
(2,2) centre, radius 5.
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 50
6. Algorithm to generate line using Bresenhams principle.
7. Explain the Phases of computer aided design process.
8. Explain software modules w.r.t any commercial model.
9. Explain Bresenhems algorithm for generation of circle.
10. Explain how ellipse can be generated using parametric equation.
11. Why CAD is beneficial ? Discuss in details.
12. Mention the role of Virtual Reality in Design & Manufacturing.
13. How CAD/CAM technologies formed the foundation for integrated factory of the future.
14. With the help of historical aspects state the changes occurred in the Product Life cycle
UNIT-II
1. Using the DDA algorithm described in the text ketch the pixels for the line drawn
from the (4,4) to (12,14).
2. Differentiate between Window and View port.
3. Discuss the window and view port features
4. What is homogeneous transformation?
5. What is Concatenated matrix?
6. Briefly describe the different techniques used for scan conversion in computer
graphics.
7. Explain 2D shear transformation.
8. Show that reflection of point about line Y=X is same as scaling followed by rotation
about origin.
9. Discuss the reflection model used in computer Graphics.
10. A triangle having vertices (2,4),(2,6) and (4,6) is reflected about line havig
y=0.5(x+4).find final position by matrix.
11. For AABC with coordinates A(3,3), B(2,8) and C(4,1). Find new vertex position
reflected about a line y=8x+9
12. Write shear transformation of rectangle ABCD in both x and Y direction by 0.5
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 51
units,where A92,2),B(6,2),C(6,4) and D(2,4).
UNIT-III
1. Compare 2D and 3D wire frame models.
2. Describe the display command available in a drafting package
3. Describe the importance of curve and surface modelling computer aided graphics and
design.
4. What is the advantages of parametric programming in designing curves and surfaces.
5. Write parametric equation for brezier curve and briefly discuss its characteristics.
6. A coordinates of four data points are (2,2,0),(2,3,0),(3,3,0) and (3,2,0). Find the
equation of brezier curve and determine coordinates of point on the curve as u=0,0.25
0.5,.75 and 1.
7. Explain (i) Bezier surface (ii) B-splines surface
8. Draw a brezier sline for the following control points. (0,0),(4,3),(8,4) and (12,0).
9. Compare the splines for the same control point created by B-splines and Bezier
splines techniques
UNIT-IV
1. Discuss the principle of finite element modelling and analysis for
optimised design of mechanical componenets.
2. Describe the general steps involved in a finite element analysis.
3. Enumerate the various design problem that can be handled by FEA.
4. Distinguish between flexibility and stiffness methods used in FEA.
5. Give some examples on plane stress and plane strain problem on
machine design.
6. Differentiate between isoparametric and non linear elements.
7. Describe a step by step procedure in solving a design problem using
FEA.
8. Describe the various approaches to create a finite element model from a solid model.
ME 308 COMPUTER AIDED DESIGNAND ANALYSIS S6 ME
COURSE HANDOUT: S6 Page 52
9. What is a stiffness matrix.
UNIT-V&VI
1. Element area = 1.5 in2, E=30,000,000, Element length = 5 feet
Write the stiffness matrix for the structure. The bar is vertical. Show
all work.
2. Using a different load, the element shown in Problem 1 deforms by
0.02 inches in length. What is the stress in the material? Use a finite
element approach to solve the problem. Show all work.
3. A composite shaft is subjected to load as shown in fig (8). Determine displacements and
stresses in each section
4. Describe isoparametric formulation (using minimum PE theorem)
5. Discuss about Gauss Quadrature
Prepared by Approved by
Mr.Abinson Paul N Dr. Thankachan T Pullan
(Faculty) (HOD)
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 53
8. ME312 METROLOGY AND INSTRUMENTATION
8.1 COURSE INFORMATION SHEET
PROGRAMME: ME DEGREE: BTECH
COURSE: METROLOGY AND
INSTRUMENTATION
SEMESTER: 6 CREDITS: 4
COURSE CODE: ME312
REGULATION: 2016
COURSE TYPE: CORE
COURSE AREA/DOMAIN: PRODUCTION
AND INDUSTRIAL ENGINEERING
CONTACT HOURS: 3 (Tutorial)
Hours/Week.
CORRESPONDING LAB COURSE CODE
(IF ANY): MATERIAL TESTING LAB
LAB COURSE NAME: NA
SYLLABUS: UNIT DETAILS HOURS
I Concept of measurement:-Introduction to Metrology; Need forhigh precision
measurements; Terminologies in Measurement-Precision, accuracy,
sensitivity, calibration. Errors in Measurement, types of errors, Abbe’s
Principle. Basic standards of length- Line standard, End standards,
Wavelength standard; Various Shop floor standards. Linear Measurement –
Slip gauges, wringing, grades; Surface plate; Dial indicators; Height gauges
and Vernier calipers. Comparators- mechanical, electrical, optical and
pneumatic.Angular Measurement – Bevel protractor; Sine Bar, principle and
use of sine bar, sine centre; Angle gauges. Sprit level; Angle Dekkor;
Clinometers.
7L
II Limits and Limit gauges – Making to suit, selective assembly, systems of
limits and fits; Types of fits; Hole basis system and Shaft basis system.
Standard systems of limits and fits; Shaft and Hole system; Tolerance,
allowance and deviation (as per BIS). Simple problems on tolerance and
allowance, shaft and hole system. Limit Gauges – GO and NO GO gauges;
types of limit gauges. Gauge design - Taylor’s principle of gauging; Gauge
tolerance, disposition of gauge tolerance, wear allowance. Optical Measuring
Instruments: - Benefits of using light waves as standards; Monochromatic
light; Principle of Interference. Interference band using optical flat,
application in surface measurement. Interferometers – NPL flatness
interferometer, Pitter-NPL gauge interferometer.
6L
III Screw thread measurement – Screw thread terminology;
Measurement of major diameter; Measurement of minor or root diameter.
Measurement of pitch; Measurement of effective diameter with two wire
method and three wire method. Measurement of flank angle and form by
profile projector and microscope. Measurement of surface texture – Meaning
of surface texture,
roughness and waviness; Analysis of surface traces, peak to valley height,
R.M.S. value, Centre Line Average and R value, Rt, Rz etc. Methods of
7L
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 54
measuring surface roughness – Stylus probe, Tomlinson surface meter,
Talysurf; Terms used in surface roughness measurement – assessment length,
roughness width cutoff, sampling length and evaluation length. Interference
method for measuring surface roughness – using optical flat and
interferometers. Autocollimator, principle and use of autocollimator.
IV Machine tool metrology – Alignment testing of machine tools like
lathe, milling machine, drilling machine. Advanced measuring devices –
Laser interferometers. Coordinate Measuring Machine (CMM) – Introduction
to CMM;
Components and construction of CMM.Types of CMM; Advantages and
application of CMM CMM probes, types of probes – contact probes and non
contact probes Machine Vision – Introduction to machine vision, functions,
applications and advantages of machine vision. Steps in machine vision
6L
V
Introduction to Mechanical Measurement – significance of mechanical
measurement; Fundamental methods of measurement; Classification of
measuring instrument. Stages in generalized measuring system – Sensor-
Transducer stage, Signal-Conditioning stage, Readout-Recording stage;
Types of input quantities; Active and Passive transducers.
Performance characteristic of measuring devices – Static characteristics –
Accuracy, Precision, Repeatability, Sensitivity, Reproducibility, Drift,
Resolution, Threshold, Hysteresis, Static calibration. Dynamic
characteristics- different order systems and their response-, Measuring lag,
Fidelity, Dynamic error; Types of errors in measurement. Transducers –
Working, Classification of transducers.Motion and Dimension measurement –
LVDT – Principle, applications, advantages and limitations.
7L
Strain and Stress Measurement - Electrical resistance strain gauge
- Principle, operation. Measurement of Force and Torque – Strain-Gauge
Load Cells, Hydraulic and Pneumatic load cells – basic principle and three
component force measurement using piezoelectric quartz crystal.
Torque Measurement – Dynamometers – Mechanical, Hydraulic
and Electrical. Vibration measurement – Vibrometers and Accelerometers –
Basic principles and operation. Temperature Measurement – Use of Thermal
Expansion – Liquidin-glass thermometers, Bimetallic strip thermometer,
Pressure thermometers. Thermocouples – Principle, application laws for
Thermocouples, Thermocouple materials and construction, measurement of
Thermocouple EMF. Resistance Temperature Detectors (RTD); Thermistors;
Pyrometers (Basic Principles).
7L
TOTAL HOURS 40L
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
T Anand K Bewoor, Vinay A Kulkarni, Metrology & Measurement, McGraw-Hill, 2009
T rnest O. Doebelin, Dhanesh N. Manik, Measurement Systems Application and Design,
McGraw-Hill, 2004
T Galyer J.F.W., Schotbolt C.R., Metrology for Engineers, ELBS,1990
T Thomas G. Beckwith, John H. L., Roy D. M., Mechanical Measurements, 6/E , Pearson
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 55
Prentice Hall, 2007
R ASME, Hand book of Industrial Metrology,1998
R Hume K. J., Engineering Metrology, Macdonald &Co. Ltd.,1990
R J.P.Holman, Experimental Methods for Engineers,Mcgraw-Hill, 2007
R Sharp K.W.B., Practical Engineering Metrology, Sir Isaac Pitman & Sons Ltd.,1958
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
BE 101 - 02 Introduction to Mechanical
Engineering Sciences.
Knowledge about various
Mechanical components.
I
COURSE OBJECTIVES: 1 Understand the working of linear and angular measuring instruments.
2 To familiarize with the working of optical measuring instruments and fundamentals of
limits and limit gauges.
3 To give basic idea about various methods for measurement of screw thread and surface
finish parameters.
4 To give an exposure to advanced measuring devices and machine tool metrology
5 To provide students an overview of mechanical measurement systems and principle of
instruments for motion and dimension measurement.
6 To provide basic idea about working principle and applications of devices for
measurement of force and torque; strain and stress and temperature.
COURSE OUTCOMES:
SNO DESCRIPTION Bloom’s
Taxonomy
Level
CME312.1
Will be able Understand the principle of linear and angular
measuring instruments and will apply the acquired knowledge for
the accurate and precise measurement of a given quantity.
Understand
(level 2)
Apply
(Level 3)
CME312.2
Will demonstrate the ability to apply the principle of limits, fits and
tolerance while designing and manufacturing the components of
their requirement.
Apply,
(level 3,)
CME312.3
Will understand the fundamentals of various methods for the
measurements of screw threads , surface roughness parameters and
the working of optical measuring instruments.
Understand
(level 2)
CME312.4 Will become familiarized with various advanced measuring devices and machine
tool metrology.
Understand
(level 2)
CME312.5
Will be able to use various devices for measuring torque, force,
strain, stress and temperature.
Apply
(level 3)
CME312.6 Demonstrate the ability to analyze the results of various measuring
systems and instruments for motion and dimensional measurements
Analyze
(level 4)
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 56
and can infer the results to give better conclusions.
CO-PO AND CO-PSO MAPPING PO
1 PO 2
PO 3
PO 4
PO 5
PO 6
PO 7
PO 8
PO 9
PO 10
PO 11
PO
12
PSO 1
PSO 2
PSO 3
CME312.1 3 - 2 - - - - - - - - - - 3 -
CME312.2 3 - 2 - - - - - - - - - - 3 -
CME312.3 3 - - - - - - - - - - - - - -
CME312.4 3 - - - - - - - - - - - - - -
CME312.5 3 - - - - - - - - - - - - 3 -
CME312.6 - 3 - - - - - - - - - - 3 -
3 3 2 - - - - - - - - - - 3 -
JUSTIFICATIONS FOR CO-PO MAPPING MAPPING LOW/
MEDIUM/ HIGH
JUSTIFICATION
C312.1-PO1 3
Accurate and precision measurement requires usage of acquired
knowledge in mathematics, physics and engineering.
C312.1-PO3 2
Application of the principles of metrology can be used for identifying,
formulating, and analysing complex problems.
C312.2-PO1
3
Ability to select, calibrate and use appropriate measuring equipment
requires identification of measurend, selection of equipment by
referring standard available equipment, and analysing the results
obtained using reference values.
C312.2-PO3
2
A good knowledge in measuring equipment and an ability to calibrate
equip them to design solutions to complex engg. Problems by
measuring various parameters affecting them.
C312.3-PO1 3
Proper analysis of results to reach actual conclusion requires some
research based knowledge and research methods.
C312.4-PO1 3
Students will have a confidence to use modern measuring equipment,
tools like Lab-views.
C312.5-PO1 3
Accurate and precision measurement requires usage of acquired
knowledge in mathematics, physics and engineering.
C312.6-PO2 3
Accurate and precision measurement requires usage of acquired
knowledge in mathematics, physics and engineering.
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 57
JUSTIFICATIONS FOR CO-PSO MAPPING
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL
REQUIREMENTS:
SNO DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
1 Measurement of microscopic material\components PO5,PSO3 Student
seminar
PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC
TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN:
SINO: TOPIC RELEVENCE
TO PO\PSO
1 Modern measuring devices Seminar
WEB SOURCE REFERENCES:
1 http://nptel.ac.in/courses/112106138/
2 http://ocw.mit.edu/courses/mechanical-engineering/2-830j-control-of-
manufacturing-processes-sma-6303-spring-2008/
MAPPING LOW/MEDIUM
/
HIGH
JUSTIFICATION
C312.1-PSO2
3
Ability to select, use and analyse the results obtained
from measuring instruments help them to design, analyse
and fabricate complex designs.
C312.1-PO2
3
Ability to apply the principle of limits, fits and tolerance
while designing and manufacturing help them to design,
analyse and fabricate complex designs.
C312.2-PO2
3
Measurements of screw threads , surface roughness
parameters and the working of optical measuring
instruments help them to design, analyse and fabricate
complex designs.
C312.2-PO2
3
Familiarized with various advanced measuring devices
and machine tool metrology.help them to design, analyse
and fabricate complex designs.
C312.3-PO2
3
Analyze the results of various measuring systems and
instruments for motion and dimensional measurements
and can infer the results to give better conclusions. help
them to design, analyse and fabricate complex designs.
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 58
3 https://www.edx.org/course/introduction-oil-country-tubular-goods-
tenarisuniversity-pipe01x
4 https://www.youtube.com/watch?v=8DTt-f6wQxE
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☐ CHALK &
TALK
☐ STUD.
ASSIGNMENT
☐ WEB
RESOURCES
☐LCD/SMART
BOARDS
☐ STUD.
SEMINARS
☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD.
SEMINARS
☐ TESTS/MODEL
EXAMS
☐ UNIV.
EXAMINATION
☐ STUD. LAB
PRACTICES
☐ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐
CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☐ ASSESSMENT OF COURSE OUTCOMES
(BY FEEDBACK, ONCE)
☐ STUDENT FEEDBACK ON
FACULTY (TWICE)
☐ ASSESSMENT OF MINI/MAJOR
PROJECTS BY EXT. EXPERTS
☐ OTHERS
8.2 COURSE PLAN
DAY MODULE TOPIC PLANNED
1 I ERRORS IN MEASUREMENT
2 I STANDARDS IN MEASUREMENT
3 I LINEAR MEASUREMENT
4 I COMPARATORS
5 I ANGULAR MEASUREMENT-SINE BAR , BEVEL PROTRACTOR
6 I ANGLE DECCOR
7 I CONCLUSION
8 II LIMIT AND LIMIT GAUGES
7 II SYSTEM OF LIMITS AND FITS
8 II PROBLEMS-TOLERANCE
9 II LIMIT GAUGES
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 59
10 II OPTICAL MEASURING DEVICES
11 II OPTICAL FLAT
12 II GAUGE DESIGN
13 II INTERFEROMETRY
14 III MEASUREMENT OF PITCH
15 III MEASUREMENT OF FLANK ANGLE-PROFILE PROJECTOR, MEASUREMENT OF SURFACETEXTURE
16 III MEASUREMENT OF SURFACE TEXTURE
17 III METHOD OF MEASUREMENT OF SURFACE ROUGHNESS
18 III INTERFERANCE METHOD OF MEASURING SURFACE ROUGHNESS,AUTOCOLLIMETER
19 III REVISION
20 IV MACHINE TOOL METROLOGY
21 IV ADVANCED MEASURING DEVICE
22 IV CMM
23 IV PROBES IN MACHINE CMMM
24 IV MACHINE VISION
25 IV STEPS IN MACHINE VISION
26 IV APPLICATIONS OF MACHINE VISION
26 V STAGES IN GENERALIZED MEASURING SYSTEM
27 V PERFORMANCE CHARACTERISTICS OF MEASURING SYSTEM
28 V DYNAMIC CHARACTERISTICS
28 V TRANSDUCERS,MOTION AND DIMENSION MEASUREMENT
29 V LVDT PRINCIPLE APPLICATION & ADVANTAGES
30 V STUDENT P[RESENTATION ON ADVANCED MEASURING SYSTEM
31 V REVISION
29 VI STRAIN AND STRESS MEASUREMENT
30 VI MEASUREMENT OF FORCE AND TORQUE
31 VI TORQUE MEASUREMENT
32 VI VIBRATION MEASUREMENT
33 VI TEMPERATURE MEASUREMENT
34 VI TEMPERATURE MEASUREMENT
35 VI THERMOCOUPLE
36 VI REVISION
37 DISCUSSION
38 DISCUSSION
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 60
39 DISCUSSION
8.3 MODULE WISE SAMPLE QUESTIONS
MODULE I & II
1. What are the uses of measurement?
2. What is legal metrology?
3. What are the objectives of metrology
4. What are the basic components of a measuring system?
5. Distinguish between Line standard and End standard.
6. Define the term Sensitivity of an instrument.
7. Differentiate between precision and accuracy.
8. Define the term reliability.
9. Give any four methods of measurement.
10. Give classification of measuring instruments.
11. Define Span.
12. Distinguish between repeatability and reproducibility.
13. Define error.
14. Distinguish between static and random error?
15. What are the sources of error?
16. Write short note on “Systematic errors”.
17. What are the factors affecting the accuracy of the measuring system?
18. Write short notes on the classification of error
19. What is the role of N.P.L
20. Explain the different types of units
21. Differentiate between precision and accuracy with suitable example.
22. State the requirements for an instrument to measure accurately.
23. What are the various possible sources of errors in measurements? What do you understand
by systematic error and random errors?
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 61
24. Explain in detail various types of errors that may arise in engineering measurements and the
ways to control it.
25. Explain the different types of standards.
26. Explain in detail the legal metrology
27. What the various standards that are being followed in India with respect to metrology
28. Explain the need of precision and accuracy in metrology
29. Explain the general measurement system with sketch
30. Give the advantages of digital vernier caliper.
31. What are the various types of linear measuring instruments?
32. List the various linear measurements?
33. List out any four angular measuring instrument used in metrology.
34. Mention any four precautions to be taken while using slip gauges.
35. What are the chances of error in using sine bars?
36. List different types of fits?
37. What is sine center?
38. Differentiate precision and non-precision instruments?
39. Explain Taylor principle in gauge design.
40. What is meant by wringing of slip gauges?
41. Name any two materials commonly used for gauges.
42. Explain the concept of interchangeability?
43. Explain the concept of selective assembly?
44. What are limit gauges?
45. What is clinometer?
46. Explain the need of angle gauges.
47. What is an angle alignment telescope?
48. Brief the usage of autocollimator.
49. What are measurement standards?
50. What effect will temperature variation have on precision measurements?
51. How can a vernier scale provide higher accuracy?
52. What are dimensional tolerances, and what are their primary uses?
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 62
53. Why is an allowance different from a tolerance?
54. What are fits?
55. What is the difference between precision and accuracy?
56. If a steel ruler expands 1% because of a temperature change, and we are measuring a 2”
length, what will the measured dimension be?
57. Explain with a neat sketch how a Vernier caliper is used for linear
measurement.
58. Explain with a neat sketch how a Micrometer is used for linear measurement.
59. Explain with a neat sketch the construction and of working Height gauge.
60. Describe the precautionary measures to be taken at various stages of using slip gauges and
explain mathematically why error in sine bar increases when the angle being measured
exceeds 45˚.
61. Explain the construction and working principle of Limit Gauge with sketch.
62. Explain the gauge design terminology with procedure and neat sketch.
63. Explain the working method of angle alignment telescope with sketch.
64. Explain with a neat sketch, the construction and working of a Autocollimator.
65. What is the principle of Clinometer? How is it used for the measurement of angles?
66. Explain bevel protractor, angle gauges and spirit level with neat sketches.
MODULE III-IV
1. Name the different types of interferometer?
2. Write the application of Laser Interferometry.
3. Name the common source of light used for interferometer
4. What are the advantages of laser interferometer?
5. List some of the applications of laser interferometer.
6. What is crest and trough?
7. What is wavelength?
8. What is CMM?
9. What are the types of CMM?
10. List any four possible causes of error in CMM.
11. Name the types of accuracy specification used for CMM.
12. Discuss the application of computer aided inspection
13. State the application of CMM in machine tool metrology
14. Name the type of accuracy specifications used for CMM
15. State the applications of CMM
16. Mention the disadvantages of CMM.
17. Define Machine vision.
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 63
18. What are the basic types of machine vision system?
19. What are the advantages of machine vision system?
20. Define gray scale analysis.
21. Explain the construction and working principle of AC laser interferometer
with neat diagram?
22. Explain the construction and working principle of DC laser interferometer with neat
diagram?
23. Explain the use of laser interferometer in angular measurement.
24. Explain how the displacements are measured using laser interferometer?
25. What is meant by alignment test on machine tools? Why they are necessary?
Explain
26. Explain the construction and principle of CMM.
27. How are CMMs classified with respect to constructional features? Sketch and state their
main applications, merits and demerits.
28. Discuss the need of computers in inspection
29. Explain machine vision system and its types.
30. What are the applications of machine vision system in metrology?
MODULE V & VI
1. Define straightness?
2. Describe the precautionary measures to be taken at various stages of using
slip gauges.
3. How the gauges block are selected to built-up the length of 45.525mm?
4. How flatness is tested?
5. List out the methods of roundness measurement.
6. What are the types of gear?
7. What are the various methods used for measuring the gear tooth thickness?
8. What are the different taper measurements?
9. Name the various types of pitch errors found in screw.
10. Name the various method of measuring the minor diameter of the thread.
11. Define the effective diameter of thread.
12. Name the two corrections to be applied for the measurement of effective
diameter.
13. What is meant by “Best size wire” in screw thread measurement?
14. How Taylor’s principles are applied to screw thread gauge?
15. Explain drunken error in screw threads.
16. Define module.
17. What are the types of gears?
18. Define Lead?
19. What is GO and NO GO Gauge?
20. How straightness, flatness and roundness are measured.
21. Name the important elements of screw thread with neat sketch.
22. Explain the one wire and two wire screw thread effective diameter method.
23. Explain the construction of a screw measuring machine and explain how it is
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 64
used in measuring the minor diameter of a screw thread.
24. Draw and explain the measurement of effective diameter of a screw thread using
three wires.
25. How to measure the specifications of the screw thread by using the tool makers
microscope? Discuss in details.
26. Explain in detail the roundness testing machine.
27. Explain gear tooth vernier method of measuring the gear tooth thickness
28. Explain Base tangent method and Constant chord method of measuring the gear
tooth thickness
29. Explain Tomlinson surface meter.
30. Describe a method to find out flatness of a surface plate.
31. Give the principle of hot wire anemometer
32. State any four inferential types of flow meters
33. What is thermopile?
34. Mention the principle involved in bimetallic strip.
35. What is thermocouple?
36. What is the working principle of thermocouple?
37. Name any four method employed for measuring torque.
38. Give the composition and useful temperature range of any one commercial
thermocouple?
39. What is a Kentometer?
40. What is the principle involved in fluid expansion thermometer?
41. What is the need of inspection?
42. What are the important elements of measurements?
43. What is the basic Principle of measurement?
44. How force, torque and power are measured?
45. What is bimetallic strip?
46. What is the use of pyrometer?
47. How flow in a draft is measured?
48. What is electrical resistance thermistor?
49. What is McLeod Gauge?
50. Briefly explain various methods of measuring flow
51. Briefly explain various methods of measuring power
52. Briefly explain various methods of measuring force
53. Explain working of Pressure thermometer and resistance thermometer
54. Explain the construction and working of Venturimeter and Rotameter
55. Explain the construction and working of Bimetallic strip and Thermocouple
56. Briefly explain various methods of measuring torque 2.
57. Briefly explain various methods of measuring temperature
58. What are load cells?
ADVANCED QUESTIONS
1. How are surface roughness and tolerance of the process related?
2. How are tolerances related to the size of a feature?
ME 312 METROLOGY AND INSTRUMENTATION S6 ME
COURSE HANDOUT: S6 Page 65
3. Select gauge blocks from an 83 piece set to build up a dimension of 3.2265”
4. Use the Unilateral System for a GO/NO-GO gauge design if the calibrated temperature is
72°F
5. and the actual room temperature is 92°F. The shape to be tested is shown below.
6. What methods are used for measuring surface roughness?
7. Describe cut off.
8. Two different surfaces may have the same roughness value. Why?
9. What will be the effect of a difference between the stylus path and the surface
roughness?
10. When is waviness a desirable and undesirable design feature?
11. Set up a sine bar (with 5 inches between cylinder centres) to provide an angle of 15°.
a) What height of gauge blocks is required?
b) Suggest an appropriate set of gauge blocks from an
81 piece set. c) What is the actual angle of the sine
bar?
c) If the room temperature is 95°F and the coefficient of expansion is .000001” per
inch per °F, and the gauge blocks are calibrated to 68°F, what is the actual sine
bar angle?
d) Suggest a new gauge block stack for the conditions in d).
12. List four different reasons that a material like cheese would not be good for gauge
blocks.
13. When using a dial indicator, is parallax or the principle of alignment more significant?
Explain your answer.
14. How can you verify that a standard square is 90°?
15. Design a GO/NO-GO gauge for a 5” by 7” square hole with tolerances of ±.1” on each
dimen- sion. Show the tolerances and dimensions for the gauges
Prepared by Approved by
Mr. Manu Joseph Dr. Thankachan T Pullan
(Faculty) (HOD)
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 66
9. ME 364 TUTBOMACHINERY
9.1COURSE INFORMATION SHEET
PROGRAMME:MECHANICAL
ENGINEERING
DEGREE: BTECH
COURSE:TURBOMACHINERY SEMESTER: 6 CREDITS: 3
COURSE CODE: ME 364
REGULATION: 2015
COURSE TYPE: ELECTIVE
COURSE AREA/DOMAIN:THERMAL
SCIENCE
CONTACT HOURS:3(LECTURE) + 1(TUTORIAL)
HOUR/WEEK
CORRESPONDING LAB COURSE CODE
(IF ANY):NIL
LAB COURSE NAME:NIL
SYLLABUS:
MODULE CONTENTS HOURS
I
Definition of turbomachine, parts of turbomachines, Comparison with positive displacement machines Classification, Dimensionless parameters and their significance, Effect of Reynolds number, Unit and specific quantities, model studies.
7
II
Application of first and second laws of thermodynamics to turbomachines, Efficiencies of turbomachines. Stage velocity traingles, work and efficiencies for turbines and compressors.
8
III Centrifugal fans and blowers : Types, stage and design parameters, flow analysis in impeller blades, volute and diffusers, losses, characteristics curves and selection, fan drives and fan noise.
10
IV Centrifugal Compressors: Construction details, types, impeller flow losses, slip factor, diffuser analysis, losses and performance curves.
10
V Axial flow compressors: Stage velocity triangles, enthalpy- entropy diagrams, stage losses and efficiency, work done factor, simple stage design problems and performance characteristics.
11
VI Axial and radial flow turbines: Stage velocity diagrams, reaction stages, losses and coefficients blade design principles, testing and performance characteristics.
10
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 67
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHOR/PUBLICATION
T1 Bruneck, Fans, Pergamom Press, 1973.
T2 Dixon, S.I,Fluid Mechanics and Thermodynamics of Turbomachinery , Pergamom, Press, 1990.
T3 Ganesan .V, Gas Turbines , Tata McGraw Hill Pub. Co., New Delhi, 1999.
T4 Stepanff, A.J, Blowers and Pumps , John Wiley and Sons Inc., 1965.
T5 Yahya, S.H, Turbines, Compressor and Fans , Tata Mc Graw Hill, 1996.
R1 Earl Logan, Jr, Hand book of Turbomachinery, Marcel Dekker Inc, 1992.
R2 Shepherd, D.G, Principles of Turbomachinery , Macmillan, 1969.
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
ME205 THERMODYNAMICS CONCEPTS 3
COURSE OBJECTIVES:
1 To acquire knowledge on Turbomachines such as pumps and turbines.
2 To prepare the students to solve complex problems related to fluid forces on a turbomachines.
3 To Introduce the concepts of design aspects of Turbomachines like turbines and pumps and their
applications.
4 To understand the working of Turbomachines and do the analysis
5 Describe the operating characteristics of Turbomachines (pumps, turbines and compressors), and the
factors affecting their operation and specifications, as well as their operation in a system.
COURSE OUTCOMES:
Sl. NO DESCRIPTION
Blooms’
Taxomomy
Level
C361.1 Students will be able to define the principles and working of Turbomachines.
Knowledge
(level1)
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 68
C361.2
Students will be able to estimate velocity triangles of turbomachines and to
calculate the performance of various hydraulic machines.
Evaluate
(level 5)
C361.3
Students will be able to design an appropriate pump/turbine with reference
to given application/situation. Carry out calculations involved in design of
pump/turbine.
Synthesis
(level 6 )
C361.4
Students will be able to understand the relation between various performance
parameters and to interpret characteristic curves of a given
pump/turbine/compressor.
Evaluate (level
5)
C361.5
Students will be able to define the principles and working of various type of
compressors and turbines.
Knowledge
(level1)
CO-PO AND CO-PSO MAPPING
PO
1
PO
2
PO
3
PO
4
PO
5
PO
6
PO
7
PO
8
PO
9
PO
10
PO
11
PO
12
PSO
1
PSO
2
PSO
3
C361.1 1 1 1 - - 1 2 - - - - 3 - - -
C361.2 3 3 1 - - 2 2 - - - - 3 1 - -
C361.3 3 3 3 - - - 1 - - - - 3 - - -
C361.4 1 3 3 3 - - - - - - - - - 2 -
C361.5 1 1 1 - - 1 - - - - - - - 2 -
1- Low correlation (Low), 2- Medium correlation(Medium) , 3-High correlation(High)
JUSTIFICATIONS FOR CO-PO MAPPING
MAPPING LOW/MEDIUM/HIGH JUSTIFICATION
C361.1-PO1 L As they could use their acquired knowledge to solve engineering
problems
C361.1-PO2 L Knowledge in principles of Turbomachines helps the students to
identify many problems related to power plants and power generation.
C361.1-PO3 L Knowledge in principles of Turbomachines is the basis for a new
design.
C361.1-PO6 L Students will be Aware of safety issues for specific machinery
C361.1-PO7 M Students will able to assess environmental/ societal impact of a
particular turbine or pump installation.
C361.1-PO12 H Become aware of the requirement for advanced knowledge by
prolonged learning.
C361.2-PO1 H Analytical knowledge on the turbine performance helps the students to
solve of the engineering problems related to fluid power plants.
C361.2-PO2 H
Analytical knowledge on the turbo machinery performance help the
students to analyze engineering problems related to power producing
and power consuming machineries (Turbine/Pump).
C361.2-PO3 H Ability to apply various energy equations to find the performance of
turbo machinery is useful for designing efficient system components.
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 69
C361.2-PO7 M Knowledge on the performance on the turbine will help the students to
reduce energy wastage.
C361.2-PO12 H
Ability to apply energy equations in engineering systems helps the
students to pursue higher education in the fields like science and turbo
machinery.
C361.3-PO1 H Ability design, carry out complex calculation helps solve complex
problems.
C361.3-PO2 H Ability design, carry out complex calculation helps analyse complex
problems.
C361.3-PO3 H Ability design, carry out complex calculation helps in designing various
system components.
C361.3-PO7 L Ability to select best pump/turbine with due the consideration towards
sustainability
C361.4-PO1 L Knowledge about various performance parameters help to solve
problems.
C361.4-PO2 M
An ability to interpret characteristic curve of various turbo machinery
equip the students to review research literatures, and analyze complex
engineering problems related to hydraulic machines reaching
substantiated conclusions.
C361.4-PO3 H Knowledge on process parameter helps in better designs.
C361.4-PO3 H Ability to interpret characteristic curve help to analyse and interpret
various results to reach better conclusions.
C361.4-PO12 M Ability to interpret characteristic curves act as a foundation for higher
studies.
C361.5-PO1 L As they could use their acquired knowledge to solve engineering
problems
C361.5-PO2 L
Knowledge in principles of compressors helps the students to identify
many problems related to gas turbine power plants and power
generation.
C361.5-PO3 L Knowledge in principles of fluid Machines is the basis for a new design.
C361.5-PO6 L Students will be Aware of safety issues for specific machinery
JUSTIFATIONS FOR CO-PSO MAPPING
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS:
SI
NO DESCRIPTION
PROPOSED
ACTIONS
RELEVANCE
WITH POs
RELEVANCE
WITH PSOs
1 Euler’s Equation for Turbomachines
Class Notes and
additional classes 1,2,3,4,5 1,2
MAPPING LOW/MEDIUM/HIGH JUSTIFICATION
C361.1-PSO1 L Students can apply their knowledge in fluid science to solve
engineering problems.
C361.2-PSO2 M Design knowledge in turbine/ pumps helps to implement various
mechanical systems.
C361.3-PSO2 M Interpreting skill acquired help to analyse various systems.
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 70
WEB SOURCE REFERENCES:
1 www.nptel.ac.in
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☑ CHALK & TALK ☑ STUD. ASSIGNMENT ☑ WEB RESOURCES
☑ LCD/SMART BOARDS ☐ STUD. SEMINARS ☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☑ ASSIGNMENTS ☐ STUD. SEMINARS ☑ TESTS/MODEL EXAMS ☑ UNIV. EXAMINATION
☑STUD. LAB PRACTICES ☐ STUD. VIVA ☐MINI/MAJOR PROJECTS ☐ CERTIFICATIONS
☐ ADD-ON COURSES ☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☑ ASSESSMENT OF COURSE OUTCOMES (BY FEEDBACK,
ONCE) ☑ STUDENT FEEDBACK ON FACULTY (TWICE)
☐ ASSESSMENT OF MINI/MAJOR PROJECTS BY EXT. EXPERTS ☐ OTHERS
9.2COURSE PLAN
Module 1
Sl.
No. Topic
No. of lecture
hours Reference Books
1 Definition of a Turbomachine 1 1) A.Bruneck, Fans,
Pergamom Press, 1973.
2) Dixon, S.I, Fluid Mechanics and Thermodynamics of Turbomachinery , Pergamom, Press, 1990.
3) Ganesan .V, Gas
Turbines , Tata
McGraw Hill Pub. Co.,
New Delhi, 1999.
4) Stepanff, A.J, Blowers
and Pumps , John
Wiley and Sons Inc.,
1965.
2 Parts of turbomachine, types of fluid
machines,Turbomachines and positive
displacement machines comparison
1
3 Application of 1st law and second law applied
to a turbomachinery 1
4 Dimmensional analysis, Rayleighs method and
Buckingham Pi theorem 1
5
Nondimmensional parameters of a
turbomachine, specific speed and significance
of Pi terms
1
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 71
6 Problems on buckingham Pi theorem 1 5) Yahya, S.H, Turbines,
Compressor and Fans
, Tata Mc Graw Hill,
1996.
6) www.nptel.ac.in
7 model studies introduction 1
8 Laws of similitude, Reynolds, Eulers, Webers,
Mach or cauchy's 1
9 Static and stagnation terms, total to total
efficiency 1
10 static to static efficiency, preheat factor 1
11 Polytropic efficiency of compressor 1
12 Multistage compression, Constant Pressure
ratio 1
13 Reheat factor of turbines 1
14 polytropic efficiency of turbines 1
15 problems on efficiency of turbomachines 1
16 problems on model analysis 1
17 Eulers equation, Components of Eulers
equation, significance of components 1
18 Degree of reaction, Utilisation factor,
relationship 1
19 Centrifugal compressor, Componenets
,Operation 1
20
Velocity triangle, slip, energy equation; Power
i/p factor, loading coefficient or pressure
coefficient
1
21 Compressor Performance characteristics,
Characteristic curves 1
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 72
22 Surging, chocking in compressor 1
23 Numerical problems on centrifugal
compressor 1
24 Centrifugal fan and blowers 1
25 Types of fans and blowers 1
26 Stages and Design parameters 1
27 losses and characteristic curves 1
28 Selection of fan and drives 1
29 fan losses 1
30 Numerical problems on fans, blowers 1
31 Axial flow compressors 1
32 Stage velocity triangles 1
33 Enthalpy Entropy diagrams 1
34 Stage losses and efficiencies 1
35 Workdone factor 1
36 Performance curves 1
37 Design problems 1
38 problems on velocity triangles 1
39 numerical problems 1
40 Axial and radial flow turbines 1
41 stage velocity triangles 1
42 Reaction stages 1
ME 364 TURBOMACINERY S6 ME
COURSE HANDOUT: S6 Page 73
Prepared by Approved by
P.P.Krishnaraj Dr.Thankachan T Pullan
(Faculty) (HOD)
43 losses 1
44 Coefficients 1
45 Blade design principles 1
46 Testing 1
Total hours : 46
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 74
10. ME 372 OPERATION RESEARCH
COURSE INFORMATION SHEET
PROGRAMME: ME DEGREE: BTECH
COURSE: OPERATION RESEARCH SEMESTER: 6 CREDITS: 3
COURSE CODE: ME372
REGULATION: 2016
COURSE TYPE: ELECTIVE
COURSE AREA/DOMAIN:MATHEMATICS
CONTACT HOURS: 3 Lectures/Week.
CORRESPONDING LAB COURSE CODE
(IF ANY): NIL
LAB COURSE NAME: NA
SYLLABUS: UNIT DETAILS HOURS
I Linear programming problems-I: Mathematical formulation of LP Problems, slack, surplus and artificial Variables. Reduction of a LPP to the standard form, feasible solutions. Graphical solution method, simplex algorithm and solution using tabular method, optimality conditions and degeneracy. Duality in linear programming
7
II Transportation Problem: Formulation of transportation problem, Basic feasible solution using different methods-East West corner method, Vogel approximation method, Optimality methods, MODI method, Unbalanced transportation problem. Assignment problem. Travelling sales man problem
7
III Sequencing Problems. Problems with n jobs through 2 machines, through 3 machines Network analysis ,CPM,PERT
7
IV Queuing theory, single server problems, Multi server problems Inventory control, Manufacturing problem with and without shortage Purchasing model with shortage, Manufacturing model with shortage
7
V Decision theory. Under condition of risk. Decision under uncertainty conditions, decision tree analysis Game Theory: Introduction, 2- person zero – sum game; Saddle point; Mini-Max and Maxi-Min Theorems (statement only); Graphical solution (2x n, m x 2 game), dominance property
7
VI Simulation, types of simulation, Generation of random numbers, Monte 7
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 75
carlo simulation ,Queuing simulation model, inventory simulation model, simulation languages
TOTAL HOURS 42
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
T Miller D M and Schmidt J W, Industrial Engineering and Operation Research, Wiley and
sons ,Singapore 1990
T H.A. Taha, “Operations Research”, 5/e, Macmillan Publishing Company, 1992.
T Kalynamoy Deb. “Optimization for Engineering Design‐ Algorithms and Examples”,
Prentice‐Hall of India Pvt. Ltd., New Delhi
R Hadley, G. “Linear programming”, Narosa Publishing House, New Delhi
R Ashok D Belegundu, Tirupathi R Chandrupatla, “Optimization concepts and Application
in Engineering”, Pearson Education
R Kanti Swarup, P.K.Gupta and Man Mohan, Operations Research, Sultan Chand and
Ashok D Belegundu, Tirupathi R Chandrupatla, “Optimization concepts and Application
in Engineering”, Pearson Education ns
R J. S. Arora, Introduction to Optimum Design, McGraw-Hill Book Company
R A. Ravindran, D. T. Phillips, J. J. Solberg, Operations Research – Principles and Practice,
John Wiley and Sons.
R Papalambros & Wilde, Principles of Optimal Design, Cambridge University Press, 2008
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
- Mathematics Basic knowledge in mathematical
calculations
School
Level
MA 101 Calculus Ordinary and partial
differentiation 1
COURSE OBJECTIVES: 1 To understand the role of operation research in decision making
2 To impart the various operation research techniques for effective problem solving
3 To impart the various techniques in Linear programming problem
COURSE OUTCOMES:
SL.NO DESCRIPTION Bloom’s
Taxonomy
Level
ME372.1 On completion of this course, the students will have a thorough understanding of operation research techniques and apply them solving practical problems
Understand
(Level 2)
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 76
in industry.
ME372.2
Students will be able to apply appropriate methods for solving the engineering operation research problems
Apply
(Level 3)
ME372.3 Students will be able to analyze the practical
application of O.R in Engineering
Analyze
(Level 4)
ME372.4 Students will be able to evaluate and solve different O.R methods
Evaluate
(Level 5)
CO-PO AND CO-PSO MAPPING PO
1 PO 2
PO 3
PO 4
PO 5
PO 6
PO 7
PO 8
PO 9
PO 10
PO 11
PO 12
PSO 1
PSO 2
PSO 3
ME372.1 3 2 - - - - - - - - - - - -
ME372.2 2 2 - 3 - - - - - - 2 -
ME372.3 2 3 - - - - - - - - - - - -
ME372.4 2 2 - - - - - - - - - 2 - -
ME 372 2.2 2.3 2 - 3 - - - - - - 2 -
JUSTIFICATIONS FOR CO-PO MAPPING MAPPING LOW/MEDIUM/
HIGH JUSTIFICATION
ME372.1
PO1 H
Acquire the knowledge of the logic behind O.R
techniques
ME372.1
PO2 M
Students will get the ability to analyse the different types
optimisation problems
ME 372.2
PO 1 M
Students will be able to analyze the practical application
of O.R in Engineering
ME372.2
PO3 M
Knowledge in programming codes that are used in NC
part programming and computer aided part
programming will enable the students analyse different
programs that are being used in CNC machines.
ME372.2
PO5 H
Students will be able to analyse the different codes used
in part programming so that they can develop effective
methods
ME 372.3
PO1 M
Students will be able to evaluate and solve different O.R
methods
ME 372.3
PO2 H
Student will be able to calculate different network
technique CPM, PERT.
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 77
ME 372.4
PO1 M
Students will get to know the different parameters of
Queuing theory.
ME 372.4
PO2 M Students will be able to understand the mechanism of
ME 372.4
PO 12
M Ability to understand the new innovative methods in
simulation.
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL
REQUIREMENTS:
SNO DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
1
Dual simplex method with different type
constraints
PO2, PO12
NPTEL +
Reading
books
2 Derivation of queuing models PO1 Seminar
TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN:
SINO: TOPIC RELEVENCE
TO PO\PSO
1 Unbalanced transportation problem
PO2, PO12
WEB SOURCE REFERENCES:
1 http://www.geogebra.org/download
2 http://www.gnuplot.info/download.html
3 http://www.scilab.org/download/5.5.2
4 http://maxima.sourceforge.net/download.html
5 http://ocw.mit.edu/courses/mathematics/
6 http://www.mei.org.uk/engineering_support
7 http://www.mathcentre.ac.uk/students/types/
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☐CHALK &
TALK
☐ STUD.
ASSIGNMENT
☐ WEB
RESOURCES
☐LCD/SMART
BOARDS
☐ STUD.
SEMINARS
☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD. ☐ TESTS/MODEL ☐ UNIV.
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 78
SEMINARS EXAMS EXAMINATION
☐ STUD. LAB
PRACTICES
☐ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐
CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☐ ASSESSMENT OF COURSE OUTCOMES
(BY FEEDBACK, ONCE)
☐ STUDENT FEEDBACK ON
FACULTY (ONCE)
☐ ASSESSMENT OF MINI/MAJOR
PROJECTS BY EXT. EXPERTS
☐ OTHERS
10.2 COURSE PLAN
DAY MODULE TOPIC PLANNED
1 I Formation LPP
2 I Graphical method
3 I Problems
4 I Simplex method
5 I Problems
6 I Problems
7 I Big M method
8 I Dual of a simplex method
9 I More problems
10 I More Problems
11 II Transportation Problems
12 II VAM
13 II North west, least cost
14 II Modi Method
15 II Stepping stone method
16 II Assignment Problems
17 III Travelling salesman problem
18 III Sequencing Problems
19 III Sequencing Problems
20 III Sequencing Problems
21 III Sequencing Problems
22 III CPM
23 IV PERT
24 IV Queuing theory
25 IV single server problems
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 79
26 IV Multi server problems
27 IV Inventory control
28 IV Manufacturing problem with and without shortage
29 IV Purchasing model with shortage
30 V Manufacturing model with shortage.
31 V Decision theory.
32 V Under condition of risk
33 V . Decision under uncertainty conditions
34 V decision tree analysis
35 V Game Theory: Introduction, 2- person zero – sum game
36 V Saddle point; Mini-Max and Maxi-Min Theorems (statement only);
37 V Graphical solution (2x n, m x 2 game)
38 V dominance property
39 VI Simulation, types of simulation
40 VI Generation of random numbers
41 VI Monte carlo simulation, Queuing simulation model
42 VI inventory simulation model,
43 VI Simulation languages
10.3 MODULE WISE SAMPLE QUESTIONS
Module 1
6. Explain the application linear programming problem.
7. Solve the following LPP using simplex method. Maximize 321 523 xxxZ
Subject to 0,,:4302,46023,4204 3213213121 xxxxxxxxxx
8. Write the algorithm for simplex method.
9. Apply the principal of duality solve the LPP: Minimize 212 xxZ Subject to
0,,:32,634,33 21212121 xxxxxxxx
10. Explain Big M method.
11. Prepare a short note on artificial variable technique.
Module 2
6. Solve the transportation problem
A B C D E Supply
1 6 4 1 5 14 20
2 2 10 1 5 8 30
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 80
3 7 11 20 40 3 15
4 2 1 9 14 16 13
Required 40 6 8 18 6
7. Explain Modi method
8. A department of 5 employees with 5 jobs to be performed .The time each men will take to
perform each job is given in the effectiveness matrix How should the the jobs allocated so as to
minimize the total man hours?
Employees
.
Job 1 2 3 4 5
A 10 5 13 15 16
B 3 9 18 13 6
C 10 7 2 2 2
D 7 11 9 7 12
E 7 9 10 4 12
9. Explain Hungerian method to solve Assignment problem.
Module 3
1. Calculate the optimal schedule and corresponding make span of following 5 jobs and 3
Machine.
Job Machine 1 Machine 2 Machine 3
1 11 10 12
2 13 8 20
3 15 6 15
4 12 7 19
5 20 9 7
2. Consider the data of a project as shown in table. If the indirect cost per week is 160.Find
the optimal crashed project completion time.
Activity Normal time Normal cost Crash time Crash Cost
1-2 13 700 9 900
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 81
1-3 5 400 4 460
1-4 7 600 4 810
2-5 12 800 11 865
3-2 6 900 4 1130
3-4 5 1000 3 1180
4-5 9 1500 6 1800
3. Distinguish between CPM and PERT.
4. Explain the significance of Crashing
Module 4
1. Drive EOQ model for Purchase inventory model without shortage.
2. Hence calculate EOQ, number of orders per year and time between successive orders of
an industry which needs 15,000 units per year .The ordering cost is Rs.125 per order and
the carrying cost per year is 20% of purchase price per unit. The purchase price /unit is
Rs.75.
3. Derive qsqs WWLL ,,, for single server model with infinite capacity.
4. Customers arrive at one window drive according to poisson distribution with a mean of
10 minutes and service time per customer is exponential with mean of 6 minutes. The
space in front the window can accommodate only 3 vehicles including the serviced one.
Other vehicles have to wait outside this space. Calculate probability that an arriving
customer can drive directly to the space in front of the window and will have to wait
outside the directed space. How long an arriving customer is expected to wait before
getting the service?
Module 5
1 Explain 2 persons zero sum game and principle of dominance in game. Use
graphical method, solve the game.
A\B B1 B2 B3 B4
A1 2 2 3 -2
A2 4 3 2 6
2. Explain the strategies and methods adopted in decision theory and decision tree analysis.
3. Explain different types of game
ME 372 OPERATION RESEARCH S6 ME
COURSE HANDOUT: S6 Page 82
Module 6
7. Explain the process of Monte Carlo simulation
8. Explain different type of simulation
9. Prepare a short note on Simulation languages.
10. Explain application of simulation
Prepared by Approved by
Mr. Binu R Dr. Thankachan T Pullan
(Faculty, DBSH) (HOD, DME)
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB S6 ME
COURSE HANDOUT: S6 Page 83
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB
11.1 COURSE INFORMATION SHEET
PROGRAMME: ME DEGREE: BTECH (KTU)
COURSE: Computer Aided Design and
Analysis Lab
SEMESTER: 6 CREDITS: 1
COURSE CODE: ME332
REGULATION: 2016
COURSE TYPE: CORE
COURSE AREA/DOMAIN: Mechanical
Systems, Design and Analysis
CONTACT HOURS: 6 Lab Hours/Week.
CORRESPONDING LAB COURSE CODE
(IF ANY): NIL
LAB COURSE NAME: NA
SYLLABUS: UNIT DETAILS HOURS
I Introduction to solid modelling and Finite Element Analysis software.
Exercises on modelling and assembly:-
a. Creation of higher end 3D solid models (Minimum 3 models)
b. Creation of assembled views of riveted joints, cotter joints and shaft
couplings (minimum 3 models)
Exercise on application of Finite Element Method, Finite Volume Method to
engineering systems:-
a. Structural Analysis((minimum 3 problems)
b. Thermal Analysis(minimum 2 problems)
c. Fluid Flow Analysis(minimum 1 problem)
6 lab
hours/
week
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
R1 Daryl Logan, A First course in Finite Element Method, Thomson Learning, 2007
R2 David V Hutton, Fundamentals of Finite Element Analysis, Tata McGraw Hill,2003
R3 Ibrahim Zeid, CAD/ CAM Theory and Practice, McGraw Hill, 2007
R4 Mikell P. Groover and Emory W. Zimmer, CAD/ CAM – Computer aided design and
manufacturing, Pearson Education,1987
R5 T. R. Chandrupatla and A. D. Belagundu, Introduction to Finite Elements in Engineering,
Pearson Education, 2012
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
ME231 COMPUTER AIDED MACHINE To have basic knowledge in machine 3
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB S6 ME
COURSE HANDOUT: S6 Page 84
DRAWING LAB parts, assembly design and to
develop 2D sketch in CAD software.
ME308 COMPUTER AIDED DESIGN
AND ANALYSIS
To have basic knowledge in the
computer aided design, FEM. 6
COURSE OBJECTIVES: 1 To provide working knowledge on Computer Aided Design methods and procedures
2 To impart training on solid modelling software
3 To impart training on finite element analysis software
COURSE OUTCOMES:
SNO DESCRIPTION Bloom’s
Taxonomy
Level
C322.1 Students are capable of developing 3D models of machine
components, complex geometries etc. using CATIA V6
Apply
Level 3
C322.2 Students are capable to assembly the parts created to
develop the whole mechanism.
Apply
Level 3
C322.3 Students are capable to generate 2D sketches of the
assembled parts and provide dimensions and symbols to
generate 2D drawing.
Apply
Level 3
C322.4
Students can apply their knowledge in importing CAD
geometries and to modify and mesh using different meshing
methods and local meshing controls as a part of pre-
processing of the FE problem in ANSYS workbench
Apply
Level 3
C322.5 Students have knowledge to conduct simple structural, fluid
flow and thermal analysis problems in ANSYS.
Analyse
Level 4
CO-PO AND CO-PSO MAPPING P
O 1
PO 2
PO 3
PO 4
PO 5
PO 6
PO 7
PO 8
PO 9
PO 10
PO 11
PO
12
PSO 1
PSO 2
PSO 3
CME 322.1 3 2 3 - 3 - - - - 3 - 3 - 3 3
CME 322.2 3 2 3 - 3 - - - - 3 - 3 - 3 3
CME 322.3 3 2 3 - 3 - - - - 3 - 3 - 3 3
CME 322.4 3 2 3 - 3 - - - - 3 - 3 3 - 3
CME 322.5 3 2 3 - 3 - - - - 3 - 3 3 - 3
CME 332 (AVG.
VALUE) 3 2 3 3 3 3 3 3 3
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB S6 ME
COURSE HANDOUT: S6 Page 85
JUSTIFICATIONS FOR CO-PO MAPPING MAPPING LOW/ME-
DIUM/ HIGH
JUSTIFICATION
CME322.1-PO1 3
Students have the capability to apply fundamental
engineering knowledge in the design and modelling of
machine components
CME322.1-PO2 2 Students are capable to using first principles of mathematics
and Engineering sciences to create and analyse better design
of machine components and systems.
CME322.1-PO3 3
Students are capable of preparing 3D models as per the
design of system components that meet the specified needs
with appropriate consideration for the public health and
safety
CME322.1-PO5 3 Knowledge in using modern 3D modelling tool to develop
machine components.
CME322.1-PO10 3
Students are capable to effectively communicate about the
3D models, mechanisms generated with effective reports
and design documentation, make effective presentations,
and give and receive clear instructions regarding the design.
CME322.1-PO12 3 Recognize the need for, life- long learning in the area of
system design and analysis.
CME322.2-PO1 3
Students have the capability to apply fundamental
engineering knowledge in the design, modelling and
assembly of machine components
CME322.2-PO2 2 Students are capable to using first principles of mathematics
and Engineering sciences to create, assemble and analyse
better design of machine components and systems.
CME322.2-PO3 3
Students are capable of preparing 3D mechanism as per the
design of system components that meet the specified needs
with appropriate consideration for the public health and
safety
CME322.2-PO5 3
Knowledge in using the latest version of CATIA 3D
modelling software to assemble the parts developed to
generate the whole assembly/ mechanism.
CME322.2-PO10 3
Students are capable to effectively communicate about the
3D models, mechanisms generated with effective reports
and design documentation, make effective presentations,
and give and receive clear instructions regarding the design.
CME322.2-PO12 3 Recognize the need for, life- long learning in the area of
system design and analysis.
CME322.3-PO1 3 Students have the capability to apply fundamental
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB S6 ME
COURSE HANDOUT: S6 Page 86
engineering knowledge in the design, modelling and
assembly of machine components and to generate and
understand the 2D views of components.
CME322.3-PO2 2
Students are capable to using first principles of mathematics
and Engineering sciences to generate 2D sketches and
analyse for a better design of machine components and
systems.
CME322.3-PO3 3
Students are capable of preparing 2D Drawing of 3D
mechanism as per the design of system components that
meet the specified needs with appropriate consideration for
the public health and safety
CME322.3-PO5 3
Knowledge in using the latest version of CATIA 3D
modelling software to generate 2D sketches of assembled
parts and to provide dimensions and symbols to generate the
2D drawing.
CME322.3-PO10 3
Students are capable to effectively communicate about the
3D models, mechanisms generated with effective reports
and design documentation, make effective presentations,
and give and receive clear instructions regarding the design.
CME322.3-PO12 3 Recognize the need for, life- long learning in the area of
system design and analysis.
CME322.4-PO1 3
Students have the capability to apply fundamental
mathematics, science and engineering knowledge in the
analysis of machine components and system
CME322.4-PO2 2 Students are capable to using first principles of mathematics
and Engineering sciences to analyse machine components
and systems.
CME322.4-PO3 3
Students are capable of conducting analysis of system
components that meet the specified needs with appropriate
consideration for the public health and safety
CME322.4-PO5 3 Students are capable of conducting analysis using modern
tools like ANSYS
CME322.4-PO10 3
Students are capable to effectively communicate about the
3D models, mechanisms, systems generated and analysed
using analysis packages with effective reports and design
documentation, make effective presentations, and give and
receive clear instructions regarding the design and analysis.
CME322.4-PO12 3 Recognize the need for, life- long learning in the area of
system design and analysis.
CME322.5-PO1 3
Students have the capability to apply fundamental
mathematics, science and engineering knowledge in the
analysis of machine components and system
CME322.5-PO2 2 Students are capable to using first principles of mathematics
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB S6 ME
COURSE HANDOUT: S6 Page 87
and Engineering sciences to analyse better design of
machine components and systems.
CME322.5-PO3 3
Students are capable of conducting analysis of system
components that meet the specified needs with appropriate
consideration for the public health and safety
CME322.5-PO5 3 Students are capable of conducting analysis using modern
tools like ANSYS.
CME322.5-PO10 3
Students are capable to effectively communicate about the
3D models, mechanisms, systems generated and analysed
using analysis packages with effective reports and design
documentation, make effective presentations, and give and
receive clear instructions regarding the design and analysis.
CME322.5-PO12 3 Recognize the need for, life- long learning in the area of
system design and analysis.
JUSTIFICATIONS FOR CO-PSO MAPPING
MAPPING LOW/MEDIUM/
HIGH
JUSTIFICATION
CME322.1-
PSO2 3
Students are capable of applying the principles of design
and implementation of mechanical systems/processes
which have been learned as a part of the curriculum.
CME322.1-
PSO3 3
Develop and implement new ideas on product design and
development with the help of modern CAD tools
CME322.2-
PSO2 3
Students are capable of applying the principles of design
and implementation of mechanical systems/processes
which have been learned as a part of the curriculum.
CME322.2-
PSO3 3
Develop and implement new ideas on product design and
development with the help of modern CAD tools
CME322.3-
PSO2 3
Students are capable of applying the principles of design
and implementation of mechanical systems/processes
which have been learned as a part of the curriculum.
CME322.3-
PSO3 3
Develop and implement new ideas on product design and
development with the help of modern CAD tools
CME322.4-
PSO1 3
Apply their knowledge in the domain of engineering
mechanics, thermal and fluid sciences to solve
engineering problems utilizing the capability of modern
analysis software.
CME322.4-
PSO3 3
Develop and implement new ideas on product analysis
with the help of modern Analysis packages
CME322.5-
PSO1 3
Apply their knowledge in the domain of engineering
mechanics, thermal and fluid sciences to solve
engineering problems utilizing the capability of modern
analysis software.
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB S6 ME
COURSE HANDOUT: S6 Page 88
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL
REQUIREMENTS:
SNO DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
nil nil nil
PROPOSED ACTIONS: TOPICS BEYOND SYLLABUS/ASSIGNMENT/INDUSTRY VISIT/GUEST LECTURER/NPTEL ETC
ADD-ON PROGRAMMES:
SNO DESCRIPTION DATES RELEVENCE
TO PO\PSO
1 Certification training in Autodesk Fusion 360 for ME
students at CAD Lab of DME, RSET in association
with BIMIT, Kochi.
27th
& 28th
July
2017, 26th
&
27th
Sep 2017,
6th
& 27th
Oct
2017, 10th
Nov 2017
PO3, PO5,
PSO3
2 Certification training in CATIA V6 for ME students
at CAD Lab of DME, RSET in association with
CADMARC, Kochi.
14TH
MAY
2018 TO 18TH
MAY2018
PO3, PO5,
PSO3
WEB SOURCE REFERENCES:
1 Knuckle joint assembly -https://www.youtube.com/watch?v=GBg1Rwjcd6s
2 Screw jack assembly- https://www.youtube.com/watch?v=gTvl6gvJX9o
3 Cantilever beam structural analysis https://www.youtube.com/watch?v=u9YnCJnSmCw
4 Introduction to static structural analysis-https://www.youtube.com/watch?v=vnpq5zzOS48
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☑ CHALK & TALK ☐ STUD. ASSIGNMENT ☑ WEB
RESOURCES
☑LCD/SMART
BOARDS
☐ STUD.
SEMINARS
☑ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD.
SEMINARS
☐ TESTS/MODEL
EXAMS
☑ UNIV.
EXAMINATION
☑ STUD. LAB
PRACTICES
☑ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐
CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
CME322.5-
PSO3 3
Develop and implement new ideas on product analysis
with the help of modern Analysis packages
ME332 COMPUTER AIDED DESIGN AND ANALYSIS LAB S6 ME
COURSE HANDOUT: S6 Page 89
ASSESSMENT METHODOLOGIES-INDIRECT
☑ ASSESSMENT OF COURSE OUTCOMES
(BY FEEDBACK, ONCE)
☑ STUDENT FEEDBACK ON FACULTY
(ONCE)
☐ ASSESSMENT OF MINI/MAJOR
PROJECTS BY EXT. EXPERTS
☐ OTHERS
11.2 COURSE PLAN
SESSION TOPICS PLANNED
1
Introduction to sketcher workbench to draw 2D geometries- Standard tool bar,
profile tool bar, view tool bar, sketch tool bar, constraint tool bar, Introduction to
Part design workbench- Sketch based features toolbar - Tutorial 1
2 Part design workbench- Dress up feature tool bar, Transformation feature tool bar
- Tutorial 2 (IC Engine Piston)
3 Part design workbench-Measure, surface based feature tool bar, Drafting
workbench- Tutorial 3 (Pipe Bend)
4 Assembly design workbench tools- Engineering connections tool bar- Assembly 1
(Rivet Joint)
5 Assembly design workbench tools- Engineering connections tool bar- Assembly 2
(Socket and Spigot)
6 Assembly design workbench tools- Engineering connections tool bar- Assembly 3
(Flanged coupling)
7 Introduction to ANSYS workbench- static structural solver- Tutorial 4 (Beam
Analysis)
8 Meshing Methods – Local meshing tools, Tutorial 5 (Structural Analysis problem)
9 Introduction to CFD solver- Fluent- Tutorial 6 (CFD analysis of signal post)
10 Structural analysis of traffic signal post coupled with CFD solver
11 Introduction to steady state thermal solver- Tutorial 7 (Thermal analysis problem)
12 Tutorial 8 (Thermal analysis problem)
Prepared by Approved by
Mr. Jithin P. N. Dr. Thankachan T Pullan
(Faculty) (HOD)
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 90
12. ME334 MANUFACTURING TECHNOLOGY LAB II
12.1 COURSE INFORMATION SHEET
PROGRAMME: ME DEGREE: BTECH
COURSE: MANUFACTURING
TECHNOLOGY LAB II
SEMESTER: 6 CREDITS: 1
COURSE CODE: ME334
REGULATION: 2016
COURSE TYPE: CORE
COURSE AREA/DOMAIN: PRODUCTION
& INDUSTRIAL ENGINEERING
CONTACT HOURS: 6 Lab hours/Week.
CORRESPONDING THEORY COURSE
CODE (IF ANY): ME312
THEORY COURSE NAME: Metrology &
Instrumentation
SYLLABUS: EXPERIMENT DETAILS HOURS
Exercise on grinding machine 1
Study and preparation of programme, simulation and exercise on CNC lathe:-
turning, step turning, taper turning, thread cutting, ball and cup turning etc.
2
Study and preparation of programme, simulation and exercise on CNC
milling machine: - surface milling, pocket milling, contour milling etc.
2
Basics for mechanical measurements
Calibration of vernier caliper, micrometer and dial gauge etc.
Determination of dimensions of given specimen using vernier caliper,
micrometer, height gauge, bore dial gauge etc.
Determination of dimensions of a rectangular, square, cylindrical specimens
using slip gauges and comparing with height gauge/vernier caliper etc
1
Experiments on Limits, Fits and Tolerance
Determine the class of fits between given shaft and hole. etc. 1
Linear measurements
Study of different linear measuring instruments.
Calibration of LVDT using slip gauges.
1
Straightness error measurement
Study of different straightness error measuring instruments – basic principle
of auto collimator and spirit level.
Measurement of straightness error of a CI surface plate using auto collimator
and comparing with sprit level.
laser interferometer used to determine straightness error
To check straightness error of a straight edge by the wedge method using slip
gauges.
1
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 91
Angle measurements
Angular measurements using bevel protractor, combination sets, clinometers,
angle dekkor etc.
Measurement of angle and width of a V-block and comparing with
combination sets.
Measurement of angle using sine bar of different samples.
1
Out of roundness measurement
Study of different methods used for measurement out of roundness
Measurement of out of roundness using form measuring instrument
Measurement of out of roundness using V-block and dial gauge
Measurement of out of roundness using bench centre and dial gauge etc.
1
Screw thread measurement
Measurement of screw thread parameters using two wire and three wire
method.
Measurement of screw thread parameters using tool maker’s microscope etc.
Measurement of screw thread parameters using thread ring gage, thread plug
gage, thread
snap gage, screw thread micrometer, optical comparator etc.
1
Bore measurement
Measurement of a bore by two ball method.
Measurement of a bore by four ball method.
Bore measurement using slip gauges and rollers.
Bore measurement using bore dial gauge etc.
1
Calibration and determination of uncertainties
Strain measurement using strain gauge load cells.
Calibration of a cantilever strain gauge load cell.
Rotation measurement
Determination of rpm using tachometer, optical tachometer and stroboscope,
etc.
1
Area determination
Study of planimeter and Green's theorem
Determination of given irregular area using planimeter.
1
Gear metrology
Types of gears – gear terminology – gear errors - study of Profile Projector.
Measurement of profile error and gear parameters using profile projector etc.
Use of Comparators
Exercise on comparators: mechanical, optical, pneumatic and electronic
comparators.
1
Use of Tool makers microscope
Study of tool maker’s microscope – use at shop floor applications.
Measurement of gear tooth parameters using tool maker’s microscope.
Measurement of different angles of single point cutting tool using tool
maker’s microscope.
1
Surface roughness measurement
Measurement of surface roughness using surface profilometer /roughness
measuring machine of turned, milled, grounded, lapped and glass etc.,
specimens.
1
Squareness measurement
Determination of squareness of a trisquare using angle plate and slip gauges. 1
Flatness measurement 1
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 92
Study of optical flat and variation of fringe patterns for different surfaces.
Determination of parallelism error between micrometer faces.
Compare given surface using optical flat with interpretation chart.
Vibration measurement
Measurement of displacement, velocity and acceleration of vibration. 1
Use of Pneumatic comparator
Checking the limits of dimensional tolerances using pneumatic comparator
Calibration using air plug gauge etc.
1
A minimum of 12 experiments are mandatory out of total 18 experiments but the experiments
mentioned in exercises on CNC machines are mandatory.
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHORS/PUBLICATION
T1 Sharp K.W.B. and Hume, Practical Engineering Metrology, Sir Isaac Pitman and sons
Ltd, London,1958
T2 Collett, C.V. and Hope, A.D, Engineering Measurements, Second edition,
ELBS/Longman,1983
R1 Yoram Koren, Numerical Control of Machine Tools, McGraw-Hill,1983
R2 Shotbolt C.R. and Gayler J.F.W, Metrology for Engineers, 5th
edition, ELBS,
London,1990
COURSE PRE-REQUISITES:
C.CODE COURSE NAME DESCRIPTION SEM
ME312 Metrology and Instrumentation
Students are required to have
knowledge in metrology,
measuring devices and
equipments.
6
ME306 Advanced Manufacturing
Technology
Students should require
knowledge about CNC part
programming codes.
6
ME303 Machine Tools and Digital
Manufacturing
Knowledge about tool signature
is required for the student to
carry out tool angle
measurements.
5
BE101-02 Introduction to Mechanical
Engineering Sciences
Students should attain
knowledge in gear terminology. 1
- Mathematics Basic knowledge in mathematical
calculations
School
Level
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 93
COURSE OBJECTIVES: 1 To provide programming practice on CNC machine tools
2 To impart knowledge on the fundamental concepts and principles of metrology
3 To explain the need of various modern measuring instruments and precision measurements
COURSE OUTCOMES:
SL.NO DESCRIPTION Bloom’s
Taxonomy
Level
CME334.1 Students will be able to select and use different linear and angle measuring devices like vernier calipers, micrometers, bevel protractors, slip gauges etc.
Understand
(level 2)
Apply
(level 3)
CME334.2
Students will be able to use equipments like Surface Roughness tester, Profile projector, and Tool makers Microscope to find out parameters of gear, thread, tool and surface roughness.
Apply
(level 3)
CME334.3 Students will be able to do the process of calibration by carrying out experiments on devices like strain gauge, LVDT, and Roughness tester.
Apply
(level 3)
CME334.4
Students will be able to understand about CNC machine tool and also to write NC part programming statements to carry out the machining processes using CNC machine tool.
Understand
(level 2)
Apply
(level 3)
CME334.5 Students will be able to make inferences during different measurement processes.
Analyze
(level 4)
CME334.6 Students will be able to perform, analyse and infer the experiments as a team.
Analyze
(level 4)
CO-PO AND CO-PSO MAPPING PO
1 PO 2
PO 3
PO 4
PO 5
PO 6
PO 7
PO 8
PO 9
PO 10
PO 11
PO 12
PSO 1
PSO 2
PSO 3
CME334.
1 2 1 - - - - - - - - - - 1 - -
CME334.
2 - 3 - - - - - - - - - 3 - 3
CME334.
3 3 - - - - - - - - - - - - 2 -
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 94
CME334.
4 2 - - - 3 - - - - - - - - - 3
CME334.
5 - 3 - 2 - - - 2 3 1 - - - - -
CME334.
6 - 2 - 2 - - - 3 3 1 - - - - -
CME334 2.3 2.2 - 2 3 - - 2.5 3 1 - 3 1 2 3
JUSTIFICATIONS FOR CO-PO MAPPING MAPPING LOW/MEDIUM/
HIGH JUSTIFICATION
CME334.1-
PO1 M
Knowledge about the measuring instruments will enable
students to carry out accurate and precise
measurements.
CME334.1-
PO2 L
Students will get an idea about how to solve a measuring
problem by properly using the measuring instruments
available in the lab.
CME334.2-
PO2 H
Parameters of engineering components like gear, tools,
thread, etc can be found out by using the knowledge that
the students gained from the lab equipments during lab
sessions.
CME334.2-
PO12 H
An overview of technological changes that may happen
in finding out surface roughness, gear parameters,
thread parameters, etc will be available for the students
after the experiment works that had been carried out on
the modern lab equipments available in the lab.
CME334.3-
PO1 H
Knowledge about the importance of precision and
accuracy of instruments will enable students to carry out
calibration set up as a part of experiment.
CME334.4-
PO1 M
Students will obtain knowledge about NC part
programming and will be able to directly input the
programming knowledge to the CNC machine.
CME334.4-
PO5 H
Students will gain practical knowledge in CNC machine
after acquiring knowledge about NC part programming.
CME334.5-
PO2 H
While doing experiments and calculations students will
get to know how to analyse a problem and also they will
be able to make inferences form it.
CME334.5-
PO4 M
Students will be able to analyse, interpret and synthesis
the data that they obtained from the experiment and will
make conclusions from the results.
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 95
CME334.5-
PO8 M
To become a professional, students required to have
ethics which will be practiced while making inferences
from the experiments and also by obeying the rules for
timely submission of records, regularity and punctuality
in attending lab sessions.
CME334.5-
PO9 H
Students can avoid the possibility of errors in
measurements by working as a group and they can find
out inferences for the reason to occurrence of such
errors.
CME334.5-
PO10 L
Communication about possible sources of errors will
enable students to avoid the causes while doing the
experiments.
CME334.6-
PO2 M
Students will get the ability to analyse the problem that
they will face while experimenting in groups.
CME334.6-
PO4 M
Investigating the inferences and conclusions in groups
will make students to work as a group to find out right
solutions for problems.
CME334.6-
PO8 H
Students will experience the importance of being involve
in doing experiments as a team thereby gaining
professional ethics which are required while working in
industry.
CME334.6-
PO9 H
By doing group wise experiments, students will get to
know how to work as a group and while doing the
analysis part they will use their individual effort to make
inferences from the results.
CME334.6-
PO10 L
Group wise experiments will enable students to
communicate properly within the group and they can
develop that skill which will be useful for their career.
JUSTIFICATIONS FOR CO-PSO MAPPING
MAPPING LOW/MEDIUM/
HIGH
JUSTIFICATION
CME334.1-
PSO1 L
Understanding of mechanism and principle of
measuring devices will help the students to carry out
measurements accurately.
CME334.2-
PSO3 H
Ability to use modern equipments available for
measuring surface roughness, tool angles, gear
parameters using roughness tester, tool makers
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 96
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSIONAL
REQUIREMENTS:
DESCRIPTION RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
NIL - -
TOPICS BEYOND SYLLABUS/ADVANCED TOPICS/DESIGN:
SINO: TOPIC RELEVENCE
TO PO\PSO
PROPOSED
ACTIONS
1 Use of CMM PO1, PO2,PO5 Visit to
industries
WEB SOURCE REFERENCES:
1 http://www.mfg.mtu.edu/cyberman/quality/sfinish/terminology.html
2 https://www.youtube.com/watch?v=D3J41HE_RMA
3 nptel.ac.in/courses/112106068/31
4 http://reotemp.com/thermocoupleinfo/thermocouple-vs-RTD.htm
5 www.ignou.ac.in/upload/Unit-7-62
6 https://www.isa.org/standards-and-publications/isa-publications/intech-
magazine/automation-basics/thermocouples-versus-rtds/
7 http://www.differencebetween.net/science/difference-between-rtd-and thermocouple/
8 http://nptel.ac.in/courses/105106114/pdfs/Unit4/4_1g%20a.pdf
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☐CHALK & ☐ STUD. ASSIGNMENT ☐ WEB ☐LCD/SMART
microscope, profile projector.
CME334.3-
PSO2 M
Studies on the need of calibration and the procedure
will bring the students attention to carry out
calibration setup before the start of every
measurement.
CME334.4-
PSO3 H
After gaining knowledge in CNC part programming,
students can work on CNC machines which is one of
the modern technology used in most of the industries
for machining operations.
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 97
TALK RESOURCES BOARDS
☐ STUD.
SEMINARS
☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD.
SEMINARS
☐ TESTS/MODEL
EXAMS
☐ UNIV.
EXAMINATION
☐ STUD. LAB
PRACTICES
☐ STUD. VIVA ☐ MINI/MAJOR
PROJECTS
☐
CERTIFICATIONS
☐ ADD-ON
COURSES
☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☐ ASSESSMENT OF COURSE OUTCOMES
(BY FEEDBACK, ONCE)
☐ STUDENT FEEDBACK ON
FACULTY (ONCE)
☐ ASSESSMENT OF MINI/MAJOR
PROJECTS BY EXT. EXPERTS
☐ OTHERS
12.2 COURSE PLAN
DAY EXPERIMENT PLANNED
1 Measurement of linear dimensions
2 Measurement of internal diameter using 4 ball method
3 Calibration of Strain gauge
4 Calibration of LVDT
5 Measurement of thread parameters using tool maker’s microscope
6 Measurement of angle using bevel protractor
7 Measurement of tool angles using tool maker’s microscope
8 Measurement of Surface roughness
9 Measurement of Chordal gear tooth thickness using profile projector
10 Measurement of Roundness
11 Measurement of angle using Sine Bar
12 Exercise in CNC Lathe
12.3 VIVA SAMPLE QUESTIONS
1. What is difference between accuracy and precision?
2. What do you mean by calibration?
ME334 MANUFACTURING TECHNOLOGY LAB II S6 ME
COURSE HANDOUT: S6 Page 98
3. Name the types of linear measuring devices, with examples.
4. What is a slip gauge? What is it used for? What are the different grades of slip gauges?
5. What is the difference between sensitivity and responsiveness?
6. What do you mean by resolution of an optical measuring device?
7. What is wringing of slip gauges?
8. Name any 3 organizations responsible for evolving standards of metrological
instruments.
9. What do you mean by measurement error? Types of errors with examples.
10. What are the different standards for linear measurements?
11. What do you mean by tolerance? How do you specify it? What is limit and fits? What are
the different types of fits?
12. According to IS, how many types of standard deviation are permissible?
13. What are gauges and what are they used for?
14. Examples for different types of gauges.
15. What are pitch and feeler gauges used for?
16. What is a comparator? What is it used for?
17. Which are the different types of comparators.
18. How is sine bar use to measure angles?
19. What is the difference between roughness and waviness?
20. What is lay in roughness measurement?
21. What are the different methods for measuring surface finish?
Prepared by Approved by
Mr. Jeffin Johnson Dr. Thankachan T Pullan
(Faculty, DME) (HOD, DME)
ME 352 COMPREHENSIVE EXAMINATION S6 ME
COURSE HANDOUT: S6 Page 99
13. ME 352 COMPREHENSIVE EXAMINATION
13.1 COURSE INFORMATION SHEET
PROGRAMME:MECHANICAL
ENGINEERING
DEGREE: BTECH
COURSE: Comprehensive Examination SEMESTER: 6 CREDITS: 2
COURSE CODE: ME 352
REGULATION: 2016
COURSE TYPE: CORE
COURSE AREA/DOMAIN:
MECHANICAL ENGINEERING
CONTACT HOURS: 2 HOUR/WEEK
CORRESPONDING LAB COURSE CODE
(IF ANY):NIL
LAB COURSE NAME:NIL
SYLLABUS:
MODULE CONTENTS HOURS
Oral examination – To be conducted weekly during the slot allotted for the course in the curriculum
(@ three students/hour) – 50 marks
Written examination - To be conducted by the Dept. immediately after the second internal
examination– common to all students of the same branch – objective type (1 hour duration)– 50
multiple choice questions ( 4 choices) of 1 mark each covering all the courses up to and including
semester V – no negative marks – 50 marks.
I Oral Examination
Mechanical Engineering branch subjects up to and including semester V
II
Witten Examination: Part A
( 40 questions – minimum 6 questions from each course)
Mechanical Engineering
1 ME201 Mechanics of Solids
2 ME205 Thermodynamics
3 ME210 Metallurgy & Materials Engineering
4 ME206 Fluid Machinery
5 ME220 Manufacturing Technology
6 ME301 Mechanics of Machinery
80%
III
Written Examination: Part B
COMMON COURSES FOR ALL BRANCHES (10 questions)
1 MA101 Calculus ( 1 question)
2 MA102 Differential Equations ( 1 question)
20%
ME 352 COMPREHENSIVE EXAMINATION S6 ME
COURSE HANDOUT: S6 Page 100
3 BE100 Engineering Mechanics ( 2 questions)
4 BE110 Engineering Graphics ( 2 questions)
5 BE103 Introduction to Sustainable Engineering ( 2 questions)
6 BE102 Design & Engineering (2 questions)
TEXT/REFERENCE BOOKS:
T/R BOOK TITLE/AUTHOR/PUBLICATION
T1 Given in the curriculum
COURSE PRE-REQUISITES: NIL
C.CODE COURSE NAME DESCRIPTION SEM
- - - -
COURSE OBJECTIVES:
1 To assess the comprehensive knowledge gained in basic courses relevant to the branch of study.
2 To comprehend the questions asked and answer them with confidence.
COURSE OUTCOMES:
Sl. NO DESCRIPTION
Blooms’
Taxomomy
Level
CME352.
1
The students will be confident in discussing the fundamental aspects
of any engineering problem/situation and give answers in dealing with
them.
Knowledge
Level 1
CO-PO AND CO-PSO MAPPING
PO
1
PO
2
PO
3
PO
4
PO
5
PO
6
PO
7
PO
8
PO
9
PO
10
PO
11
PO
12
PSO
1
PSO
2
PSO
3
CME352.1 2 2 1 - - 1 - - 1 - 2 1 - -
-
CME352 2 2 1 - - 1 - - 1 - 2
1 - - -
1- Low correlation (Low), 2- Medium correlation(Medium) , 3-High correlation(High)
ME 352 COMPREHENSIVE EXAMINATION S6 ME
COURSE HANDOUT: S6 Page 101
JUSTIFICATIONS FOR CO-PO MAPPING
MAPPING LOW/MEDIUM/HIGH JUSTIFICATION
CME352.1-
PO1
2 comprehensive knowledge gained from mathematics and engineering
fundamentals contribute to solving complex engineering problems
CME352.1-
PO2
2 comprehensive knowledge gained in basic courses relevant to the
Mechanical Engineering banch contribute to Identify, formulate, review
research literature and analyze complex engineering problems
CME352.1-
PO3
1 comprehensive knowledge gained in basic courses can utilize in design
and develop solutions for complex engineering problems
CME352.1-
PO6
1 comprehensive knowledge gained in Design & Engineering courses
helps to Apply reasoning informed by the contextual knowledge to
assess societal and safety issues and the consequent responsibilities
relevant to the professional engineering practice.
CME352.1-
PO9
1 comprehensive knowledge gained in basic Mechanical Engineering
courses will enable the student to become a productive member of a
design team
CME352.1-
PO11
2 comprehensive knowledge gained in basic courses in ME contribute to
Demonstrate knowledge and understanding of the engineering principles
and apply these to one’s own work.
CME352.1-
PO12
1 The student will become aware of the need for lifelong learning and the
continued upgrading of technical knowledge
CME352.1-
PO1
2 comprehensive knowledge gained from mathematics and engineering
fundamentals contribute to solving complex engineering problems
GAPS IN THE SYLLABUS - TO MEET INDUSTRY/PROFESSION REQUIREMENTS:
SI
NO DESCRIPTION
PROPOSED
ACTIONS
RELEVANCE
WITH POs
RELEVANCE
WITH PSOs
1 NIL
NIL - -
WEB SOURCE REFERENCES:
1 www.nptel.ac.in
2 https://www.nodia.co.in/gate-previous-year-solved-papers
DELIVERY/INSTRUCTIONAL METHODOLOGIES:
☑ CHALK & TALK ☐ STUD. ASSIGNMENT ☑ WEB RESOURCES
☑ LCD/SMART BOARDS ☐ STUD. SEMINARS ☐ ADD-ON COURSES
ASSESSMENT METHODOLOGIES-DIRECT
☐ ASSIGNMENTS ☐ STUD. SEMINARS ☐ TESTS/MODEL EXAMS ☑ UNIV. EXAMINATION
ME 352 COMPREHENSIVE EXAMINATION S6 ME
COURSE HANDOUT: S6 Page 102
☐STUD. LAB PRACTICES ☑ STUD. VIVA ☐MINI/MAJOR PROJECTS ☐ CERTIFICATIONS
☐ ADD-ON COURSES ☐ OTHERS
ASSESSMENT METHODOLOGIES-INDIRECT
☑ ASSESSMENT OF COURSE OUTCOMES (BY FEEDBACK,
ONCE) ☑ STUDENT FEEDBACK ON FACULTY (ONCE)
☐ ASSESSMENT OF MINI/MAJOR PROJECTS BY EXT. EXPERTS ☐ OTHERS
13.2 COURSE PLAN
DAY TOPICS PLANNED
1 Final Evaluation –Oral Examination
2 Final Evaluation-Written Examination
Prepared by Approved by
Vishnu Sankar Dr.Thankachan T Pullan
(Faculty) (HOD)
COURSE HANDOUT: S6 Page 103