Department of Mechanical Engineering
B.Tech (Mechanical Engineering)
COURSE STRUCTURE (Applicable for 2012-13 admitted batch)
Branch: ME No of sections-2
B.Tech 5th
Semester
B.Tech 6th
Semester No of sections-2
Code Subject L T P C
HS 3405 Engineering Economics and Project Management
3+1 1
- 4
ME 3426 Design of Machine Members 3+1
1 - 4
ME 3427 Heat Transfer 3+1
1 - 4
Elective-I
ME 3428 Industrial Robotics
3+1
1
- 4 ME 3429 Refrigeration and Air Conditioning
ME 3430 Unconventional Machining Processes
Elective-II(open)
IT 3418 Cloud Computing
3+1 1 - 4
CE 3428 Disaster Management
ECE 3425 Fundamentals of Global Positioning
Systems
CHEM
3425
Industrial Safety and Hazard
Management
Code Subject L T P C
ME 3418 Basic elements of Machine design 3 1 - 4
ME 3419 Dynamics of Machinery
3
1 - 4
ME 3420 Instrumentation and control systems 3
1 - 4
ME 3421 Machine Tools &Metrology 3
1 - 4
ME 3422 Steam and Gas turbines 3
1 - 4
ME 3223 Machine Tools& Metrology Lab - - 3 2
ME 3224 Production Drawing Practice - - 3 2
ME 3225 Thermal Engineering. Lab - - 3 2
Total 15 5 9 26
ME 3431 Operation Research
EEE 2437 Renewable energy sources
CSE 3416 Soft Computing
ME 3232 Instrumentation & Dynamics Lab - - 3 2
ME 3233 Heat Transfer Lab - - 3 2
GMR
30001 Audit Course -
- - -
GMR
30206 Term paper
- -
3 2
Total 15 5 6 26
Department of Mechanical Engineering
B.Tech- 5th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Basic Elements of Machine Design Course Code: ME 3418
L T P C
3 1 0 4
Course Objectives
The course content enables students to: 1. Understand the design procedure and selection of material for a specific application.
2. Apply failure theories in evaluating strength of machine elements.
3. Analyze machine components subjected to static and variable loads.
4. Design machine elements like Riveted and welded joints, Bolted joints, Keys, cotters and knuckle joints, shafts and their
couplings and springs
Course Outcomes
At the end of the course students are able to:
1. Understand the design procedure and selection of material for a specific application
2. Design a component subjected to static loads based on strength and stiffness criterion.
3. Design a component when it is subjected to variable loads.
4. Provide alternate design solutions based on requirement.
UNIT – I INTRODUCTION: General considerations in the design of Engineering Materials and their properties –selection –BIS codes of
steels.
STRESSES IN MACHINE MEMBERS: Combined stresses – Torsional and bending stresses – Various theories of failure –
factor of safety – Design for strength and rigidity – preferred numbers.
STRENGTH OF MACHINE ELEMENTS : Stress concentration – Theoretical stress Concentration factor – Fatigue stress
concentration factor notch sensitivity – Design for fluctuating stresses – Endurance limit – Estimation of Endurance strength –
Goodman’s line – Soderberg’s line – Modified goodman’s line.
UNIT – II Riveted and welded joints – Design of joints with initial stresses – eccentric loading
UNIT – III Bolted joints – Design of bolts with pre-stresses – Design of joints under eccentric loading
KEYS, COTTERS AND KNUCKLE JOINTS:
Design of Keys-stresses in keys-cottered joints-spigot and socket, sleeve and cotter, jib and cotter joints- Knuckle joints
UNIT –I V
SHAFTS : Design of solid and hollow shafts for strength and rigidity – Design of shafts for combined bending and axial loads
– Shaft sizes – BIS code
SHAFT COUPLING: Rigid couplings – Muff, Split muff and Flange couplings. Flexible couplings – Modified. Flange
coupling
TEXT BOOKS: 1. Machine Design, V.Bandari Tmh Publishers
2. Machine Design, S MD Jalaludin, AnuRadha Publishers
3. Design Data hand Book, S MD Jalaludin, AnuRadha Publishers
REFERENCES:
1. Design of Machine Elements / V.M. Faires
2. Machine design / Schaum Series.
3. Machine design – Pandya & shah.
Department of Mechanical Engineering
B.Tech- 5th
Semester
SYLLABUS
(Applicable for 2012-13 admitted batch)
Course Title : Dynamics of Machinery Course Code: ME 3419
L T P C
3 1 0 4
Course Objectives
The course content enables students to:
1. Understand Synthesis and analysis by providing significant skills and experience in creating and modeling mechanisms.
2. Apply analytical skills in the mechanism synthesis process that will result in automation of the design process.
3. Apply the tools necessary for kinematic and dynamic analysis of mechanisms and machines, and the skills necessary to
consider the role of dynamics in the design of machines.
4. Understand Static and dynamic balancing of mechanisms.
Course Outcomes
At the end of the course students are able to: 1. Apply basic principles of mechanisms in mechanical systems.
2. Perform static and dynamic analysis of simple mechanisms.
3. Perform balancing of rotating and reciprocating masses.
4. Model and analyze mechanical systems subjected to vibrations.
UNIT – I
PRECESSION: Gyroscopes, effect of precession motion on the stability of moving vehicles such as motor car, motor cycle,
aero planes and ships.
Clutches: Friction clutches- Single Disc or plate clutch, Multiple Disc Clutch, Cone Clutch, Centrifugal Clutch.
BRAKES AND DYNAMOMETERS: Simple block brakes, , band brake of Vehicle, internal expanding brake. Dynamometers
– absorption and transmission types. General description and methods of operations.
UNIT – II TURNING MOMENT DIAGRAM AND FLY WHEELS: Turning moment – Inertia Torque connecting rod angular velocity
and acceleration, crank effort and torque diagrams – Fluctuation of energy – Fly wheels.
GOVERNERS: Watt, Porter and Proell governors. Spring loaded governors – Hartnell and hartung with auxiliary springs.
Sensitiveness, isochronism and hunting.
UNIT – III BALANCING: Balancing of rotating masses Single and multiple – single and different planes.
Balancing of Reciprocating Masses: Primary, Secondary, and higher balancing of reciprocating masses. Analytical and
graphical methods. locomotive balancing – Hammer blow,Swaying couple, variation of tractive efforts. Unbalanced forces and
couples – examination of “V” multi cylinder in line and radial engines for primary and secondary balancing,
UNIT – IV
VIBRATION : Free Vibration of mass attached to vertical spring – oscillation of pendulums, centers of oscillation and
suspension. Transverse loads, vibrations of beams with concentrated and distributed loads. . Whirling of shafts, critical speeds
Dunkerly’s methods, Raleigh’s method,. Simple problems on forced damped vibration Vibration Isolation & Transmissibility.
Torsional vibrations, two and three rotor systems
TEXT BOOKS: 1. Theory of Machines / S.S Ratan/ Mc. Graw Hill Publ.
2. Theory of Machines / Jagadish Lal & J.M.Shah / Metropolitan.
REFERENCES: 1. Mechanism and Machine Theory / JS Rao and RV Dukkipati / New Age
2. Theory of Machines / Shiegly / MGH
3. Theory of Machines / Thomas Bevan / CBS Publishers
4. Theory of machines / Khurmi/S.Chand.
Department of Mechanical Engineering
B.Tech-5th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Instrumentation &Control System Course Code: ME 3420
L T P C
3 1 0 4
Course Objectives
The course content enables students to:
1. Educate the operating principles and function of measuring instruments used in Engineering and process industries.
2. Be conversant with various working principles of instruments
3. Understand and analyse the behavioral characteristics of instruments
4. Learn about calibration procedure the instrument
5. Get educated about the fundamental aspects of contro; systems and their use in the context of industry applications
Course Outcomes
At the end of the course students are able to:
1. Understand working principles of basic measuring instruments
2. Select a transducer for measurement of primary and derived variables.
3. Analyze the response of a measuring instrument.
4. Analyze and design an instrumentation system.
5. Understand temperature, speed and position control systems.
UNIT-I
Definition - Basic principles of measurement - measurement systems, generalized configuration and functional descriptions of
measuring instruments - examples, dynamic performance characteristics - sources of error, classification and elimination of
error.
MEASUREMENT OF DISPLACEMENT: Theory and construction of various transducers to measure displacement - piezo
electric, inductive, capacitance, resistance,calibration.
MEASUREMENT OF TEMPERATURE: Classification - ranges – various principles of measurement - expansion, electrical
resistance - thermistor - thermocouple - pyrometers - temperature indicators.
UNIT-II MEASUREMENT OF PRESSURE: Units -classification -different principles used. manometers, piston, bourdon pressure
gauges,bellows – diaphragm gauges. low pressure measurement - thermal conductivity gauges –McLeod pressure gauge.
MEASUREMENT OF LEVEL: Direct method - indirect methods - capacitive, ultrasonic, magnetic, cryogenic fuel level
indicators – bubbler level indicators.
FLOW MEASUREMENT: Rotameter, magnetic, ultrasonic, turbine flow meter, hot-wire anemometer..
UNIT-III
MEASUREMENT OF SPEED: Mechanical tachometers – electrical tachometers - stroboscope, noncontact type of tachometer
Measurement of Acceleration and Vibration: Different simple instruments – principles of seismic instruments - vibrometer and
accelerometer using this principle.
STRESS STRAIN MEASUREMENTS: Various types of stress and strain measurements - electrical strain gauge - gauge factor
- method of usage of resistance strain gauge for bending compressive and tensile strains – usage for measuring torque, strain
gauge rosettes.
UNIT-IV MEASUREMENT OF HUMIDITY - Moisture content of gases, sling psychrometer, Absorption psychrometer, Dew point
meter.
MEASUREMENT OF FORCE, TORQUE AND POWER- Elastic force meters, load cells, torsion meters, dynamometers.
ELEMENTS OF CONTROL SYSTEMS: Introduction, importance - classification - open and closed systems,
servomechanisms-examples with block diagrams-temperature, speed & position control systems.
TEXTBOOKS: I. Measurement Systems: Applications & design by D.S Kumar.
2. Mechanical Measurements/BeckWith, Marangoni,Linehard, PHI/PE
REFERENCE BOOKS:
I. Measurement systems: Application and design, Doeblin Earnest. O.Adaptation by Manik and Dhanesh/ TMH
2. Experimental Methods for Engineers / Holman.
3. Mechanical and Industrial Measurements / R.K. Jain/ Khanna Publishers.
4. Instrumentation, measurement & analysis by B.C.Nakra & K.K.Choudhary, TMH
Department of Mechanical Engineering
B.Tech- 5th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Machine Tools & Metrology Course Code: ME 3421
L T P C
3 1 0 4 Course Objectives
The course content enables students to: 1. Acquire the knowledge of engg. metrology and its practice which is having increasing importance in industry.
2. Specifically makes the student to improve applications aspect in the masurements and control of process of manufacture
3. Impart the fundamental aspects of the metal cutting principles and their application in studying the behavior of various
machining processes.
4. Train in knowing the fundamental parts of various machine tools and their kinematic schemes.
5. Discuss various principles of jigs and fixtures which will be used hold the workpieces in various machine tools
Course Outcomes
At the end of the course students are able to: 1. Understand the cutting tool geometry, mechanism of chip formation and mechanics of orthogonal cutting.
2. Identify basic parts and operations of machine tools including lathe, shaper, planer, drilling, boring, milling and grinding
machine.
3. Design locating and clamping devices to produce a component.
4. Select a machining operation and corresponding machine tool for a specific application in real time.
5. Select a measuring instrument to inspect the dimensional and geometric features of a given component.
UNIT – I
Elementary treatment of metal cutting theory, tool geometry, chip formation and types of chips, Mechanics of orthogonal
cutting, tool life, Tool materials
Lathe – Principle of working, specification of lathe – types of lathe – work holders tool holders. Turret and capstan lathes,
work holders – tool holding devices, Principal features of automatic lathes.
UNIT – II Shaping slotting and planing machines–Principal parts – specification, machining time calculations
Drilling and Boring Machines– Principle parts, tool- holding devices, Jig Boring machine. Kinematics scheme of the drilling
and boring machines. Milling machine –Principal features, methods of indexing.
UNIT –III
Grinding machine – Principle parts, selection of a grinding wheel, Kinematic scheme of grinding machines.
Super finishing- Lapping, honing and broaching machines–Kinematics scheme of Lapping, Honing and Broaching machines.
Constructional features of speed and feed Units, machining time calculations
Principles of design of Jigs and fixtures. Principles of location - and clamping –Typical examples of jigs and fixtures.
UNIT – IV MEASUREMENT OF ANGLES AND TAPERS: Different methods – Bevel protractor – angle slip gauges – spirit levels –
sine bar – Sine plate, rollers and spheres used to determine the tapers.
OPTICAL MEASURING INSTRUMENTS: Tool maker’s microscope and its uses – collimators, optical projector – optical
flats and their uses, interferometer.
FLAT SURFACE MEASUREMENT: Measurement of flat surfaces – instruments used – straight edges – surface plates –
optical flat and auto collimator.
MEASUREMENT THROUGH COMPARATORS: Comparators – Mechanical, Electrical and Electronic Comparators,
pneumatic comparators and their uses in mass production.
SCREW THREAD MEASUREMENT: Element of measurement – errors in screw threads – measurement of effective
diameter, angle of thread and thread pitch, profile thread gauges.
GEAR MEASUREMENT: Gear measuring instruments, Gear tooth profile measurement, Measurement of diameter, pitch
pressure angle and tooth thickness.
Coordinate Measuring Machines: Types of CMM, Role of CMM, and Applications of CMM.
TEXT BOOKS:
1. Production Technology by R.K. Jain and S.C. Gupta.
2. Production Technology by H.M.T. (Hindustan Machine Tools).
REFERENCES: 1. Machine Tools – C.Elanchezhian and M. Vijayan / Anuradha Agencies Publishers.
2. Workshop Technology – B.S.Raghu Vamshi – Vol II
B.Tech- 5th
Semester
SYLLABUS
(Applicable for 2012-13 admitted batch)
Course Title: Steam and Gas Turbines Course Code: ME3422
L T P C
3 1 0 4 Course Objectives
The course content enables students to: 1. Develop the concept on Rankine’s cycle and its thermal refinement
2. Understand the various boilers and their performance
3. Develop the concept on flow steam in nozzles and related problems.
4. Give an idea on steam turbines, condensers and gas turbines and their Understand the steam condensers and related
problems.
Course Outcomes
At the end of the course students are able to:
1. Understand the concept of Rankine cycle.
2. Understand working of boilers including water tube, fire tube and high pressure boilers and determine efficiencies.
3. Analyze the flow of steam through nozzles
4. Evaluate the performance of condensers and steam turbines
5. Evaluate the performance of gas turbines
UNIT I
Vapour power cycles: Thermodynamic analysis of simple Rankine cycle- performance improvement of simple Rankine cycle
by Reheating and Regeneration.
Steam Generators: Classification of Steam Generators, Basic construction and working details of steam generators-Cochran,
Bobcock & wilcock, Benson and Loeffler boilers-Boiler performance parameters-Equivalent evaporation and boiler efficiency,
Boiler mountings and accessories, Draft System: Theory of Natural, Induced, Forced and Balance Draft.
UNIT II
Steam nozzles: Function of nozzle – applications - types, Flow through nozzles, thermodynamic analysis – assumptions -
velocity of nozzle at exit-Ideal and actual expansion in nozzle, velocity coefficient, condition for maximum discharge, critical
pressure ratio, criteria to decide nozzle shape: Super saturated flow, its effects, degree of super saturation and degree of under
cooling - Wilson line.
Steam Condensers: Classification of condensers – working principle of different types – vacuum efficiency and condenser
UNIT III Steam Turbines: Classification – Impulse turbine; Mechanical details – Velocity diagram – effect of friction – power
developed, axial thrust, blade efficiency – condition for maximum efficiency. Velocity compounding, pressure compounding,
Pressure velocity compounding,Velocity and Pressure variation along the flow – combined velocity diagram for a velocity
compounded impulse turbine.
Reaction Turbine: Mechanical details – principle of operation, thermodynamic analysis of a stage, degree of reaction –
velocity diagram – Parson’s reaction turbine – condition for maximum efficiency
UNIT IV Gas turbines: Introduction Ideal Simple-Cycle Gas Turbine Analysis of the Ideal Cycle Analysis of the Open Simple-Cycle
Gas Turbine Maximizing the Net Work of the Cycle Regenerative Gas Turbines Inter cooling and Reheat- Combining
Intercooling, Reheat, and Regeneration.
TEXT BOOKS : 1 Power Plant Engineering-P.K.Nag-TMH
2 Gas Turbines – V.Ganesan /TMH
3 Thermal Engineering / R.K. Rajput / Lakshmi Publications
REFERENCES :
1. Thermodynamics and Heat Engines / R. Yadav / Central Book Depot
2. Gas Turbines and Propulsive Systems – P.Khajuria & S.P.Dubey - /Dhanpatrai
3. Gas Turbines / Cohen, Rogers and Saravana Muttoo / Addison Wesley – Longman
4. Thermal Engineering-P.L.Bellaney/ khanna publishers.
5. Thermal Engineering-M.L.Marthur & Mehta/Jain bros.
Department of Mechanical Engineering
B.Tech- 5th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Machine Tools and Metrology Lab Course Code: ME 3223
L T P C
0 0 3 2 Course Objectives
The course content enables students to: 1. To learn the measurement of bores by internal micrometers and dial bore indicators.
2. To learn the measurement of the Angle and taper s by Bevel protractor, Sine bars, etc.
3. To learn the Step turning and taper turning and thread cutting Drilling and Tapping on lathe machine
4. To the operations of Shaping and Planing and milling
Course Outcomes
At the end of the course students are able to: 1. Measure the bores by internal micrometers and dial bore indicators.
2. Measure the angle and taper using Bevel protractor and Sine bar.
3. Measure screw thread parameters.
4. Perform step turning, taper turning, thread cutting, drilling and tapping operations on lathe.
5. Perform operations on shaper, planer and milling machines.
6. Perform alignment tests for the evaluation of machine tool accuracy.
List of experiments
Section A: 1. Measurements of length, height, diameters by vernier calipers micrometers etc.
2. Measurement of bores by internal micrometers and dial bore indicators.
3. Use of gear teeth, Vernier calipers and checking the chordal addendum and chordal height of spur gear.
4. Machine tool “ Alignment of test on the lathe”.
5. Machine tool alignment test on milling machine.
6. Tool makers microscope and its application.
7. Angle and taper measurements by Bevel Protractor, Sine bars etc.
8. Use of spirit level in finding the flatness of surface plate.
9. Thread measurement by Two wire/three wire method or Tool makers microscope.
Section B: 1. Introduction of general purpose machine- Lathe, Drilling machine, Milling machine, Sharper, Planning machine, Slotting
machine, Cylindrical Grinder, Surface grinder and tool and cutter grinder.
2. Step turning and taper turning on lathe machine.
3. Thread cutting and knurling on lather machine.
4. Drilling and Tapping.
5. Shaping and planning.
6. Slotting.
7. Milling.
8. Cylindrical Surface Grinding.
9. Grinding of Tool angles.
Department of Mechanical Engineering
B.Tech- 5th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Production Drawing Practice Lab Course Code: ME 3224
L T P C
0 0 3 2 Course Objectives
The course content enables students to: 1. Get trained in understanding the conventional representation of different materials and machine parts.
2. Allow to study the various limits, fits and tolerances adopted in the production drawings.
3. Know about the various surface treatment symbols used
4. Learn the detail and assembly production drawings of simple components.
Course Outcomes
At the end of the course students are able to:
1. Understand the conventions used in a production drawing.
2. Determine limits and fits and allocate tolerances for machine components.
3. Convert machine drawings into production drawings.
4. Apply concepts and methods in the preparation of production drawings.
UNIT -I Conventional representation of Materials - conventional representation of parts - screw joints, welded joints, springs, gears,
electrical, hydraulic and pneumatic circuits - methods of indicating notes on drawings.
UNIT –II Limits and Fits: Types of fits, exercises involving selection I interpretation of fits and estimation of limits from tables.
UNIT -III Form and Positional Tolerances: Introduction and indication of the tolerances of from and position on drawings, deformation
of run out and total run out and their indication.
Surface roughness and its indication: Definitions - finishes obtainable from various manufacturing processes, recommended
surface roughness on mechanical components.
UNIT - IV
Heat treatment and surface treatment symbols used on drawings
Detailed/ Part drawings: Drawing of parts from assembly drawings with indications of size, tolerances, roughness, form and
position errors etc.
TEXT BOOKS:
1. Production and Drawing – K.L. Narayana & P. Kannaiah/ New Age
2. Machine Drawing with Auto CAD- Pohit and Ghosh, PE
REFERENCE :
1. Geometric dimensioning and tolerancing- James D. Meadows/ B.S Publications
2. Engineering Metrology, R.K. Jain, Khanna Publications
Department of Mechanical Engineering
B.Tech- 5th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Thermal Engineering Lab Course Code: ME3225
L T P C
0 0 3 2 Course Objectives
The course content enables students to: 1. Understand the importance and working of the heat engines
2. Find the performance of the heat engines
3. Aware of the Refrigeration and air conditioning
4. Prepare heat balance sheet
Course Outcomes
At the end of the course students are able to:
1. Evaluate the performance of IC engines.
2. Perform heat balance analysis of IC engines.
3. Evaluate the performance of a reciprocating air compressor.
4. Evaluate the performance of refrigeration and air conditioning systems.
5. Plot Valve and Port timing diagrams of 4-stroke and 2-stroke engines
6. Compile and present specifications of two and four wheelers.
List of experiments 1. I.C. Engines valve / port timing diagrams
2. I.C. Engines performance test (4 - Stroke diesel engines)
3. Evaluation of engine friction by conducting Morse test on 4-stroke multi cylinder petrol engine
4. I.e. Engines heat balance.
5. Economical speed test of an IC engine
6. To measure quality of steam by using throttling and separating calorimeter.
7. Performance test on reciprocating air compressor unit
8. COP of Refrigeration Unit
9. Performance of A/C System
10. Study of boiler
11. Team work on survey of commercial Two and Four wheelers including compilation of technical specification
and presentation
12. Dis-assembly / assembly of engines.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Engineering Economics and Project Management Course Code: HS 3405
L T P C
3 1 0 4 Course Objectives:
The course content enables students to:
1. To acquaint the basic concepts of Engineering Economics and its application
2. To know various methods available for evaluating the investment proposals
3. To gain the relevant knowledge in the field of management theory and practice
4. To understand the project management lifecycle and be knowledgeable on the various phases from project initiation
through closure
Course Outcomes:
At the end of the course students are able to:
1. Understand basic principles of engineering economics.
2. Evaluate investment proposals through various capital budgeting methods.
3. Analyze key issues of organization, management and administration.
4. Evaluate project for accurate cost estimates and plan future activities.
UNIT-I:
Introduction to Engineering Economics: 10 + 3* Concept of Engineering Economics – Types of efficiency – Theory of Demand - Elasticity of demand- Supply and law of
Supply – Indifference Curves.
Demand Forecasting & Cost Estimation:
Meaning – Factors governing Demand Forecasting – Methods – Cost Concepts – Elements of Cost – Break Even Analysis.
UNIT-II
Investment Decisions & Market Structures: 12 +5* Time Value of Money – Capital Budgeting Techniques - Types of Markets – Features – Price Out-put determination under
Perfect Competition, Monopoly, Monopolistic and Oligopoly
Financial Statements & Ratio Analysis: Introduction to Financial Accounting - Double-entry system – Journal – Ledger - Trail Balance – Final Accounts (with simple
adjustments) – Ratio Analysis (Simple problems).
UNIT-III
Introduction to Management: 11 + 3* Concepts of Management – Nature, Importance – Functions of Management, Levels - Evolution of Management Thought –
Decision Making Process - Methods of Production (Job, Batch and Mass Production) - Inventory Control, Objectives,
Functions – Analysis of Inventory – EOQ.
UNIT-IV
Project Management: 12 +4* Introduction – Project Life Cycle – Role Project Manager - Project Selection – Technical Feasibility – Project Financing –
Project Control and Scheduling through Networks - Probabilistic Models – Time-Cost Relationship (Crashing) – Human
Aspects in Project Management.
Text Books:
1. Fundamentals of Engineering Economics by Pravin Kumar, Wiley India Pvt. Ltd. New Delhi, 2012.
2. Project Management by Rajeev M Gupta, PHI Learning Pvt. Ltd. New Delhi, 2011.
Reference Books:
1. Engineering economics by Panneer Selvam, R, Prentice Hall of India, New Delhi, 2013.
2. Engineering Economics and Financial Accounting (ASCENT Series) by A. Aryasri & Ramana Murthy, McGraw Hill,
2004.
3. Project Management by R.B.Khanna, PHI Learning Pvt. Ltd. New Delhi, 2011.
4. Project Management by R. Panneer Selvam & P.Senthil Kumar, PHI Learning Pvt. Ltd. New Delhi, 2009.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Design of Machine Members Course Code: ME 3426
L T P C
3 1 0 4
Course Objectives
The course content enables students to:
1. Learn about the design procedures for complex machine members like Gears, Bearings, and Engine Parts etc.
2. Use standard design hand books and codes rather than simple strength of materials approach.
3. Be exposed to the System Design concept in place of element design approach.
Course Outcomes
At the end of the course students are able to: 1. Design journal bearings, ball and roller bearings subjected to static and dynamic loads.
2. Analyze curved beams subjected to static loads.
3. Design engine parts including connecting rod, crank shaft, pistons and cylinders.
4. Design power transmission systems including power screws, belts, pulleys, spur and helical gears.
5. Design machine tool elements including beds guide ways.
UNIT – I BEARINGS : Types of Journal bearings – Lubrication – Bearing Modulus – Full and partial bearings –Clearance ratio – Heat
dissipation of bearings, bearing materials – journal bearing design, Petroff ‘sequation – Ball and roller bearings – Static loading
of ball & roller bearings, Bearing life.
Design of curved beams: introduction, stresses in curved beams, Expression for radius of neutral axis for rectangular, circular,
trapezoidal and T-Section. Design of crane hooks, C –clamps.
UNIT – II ENGINE PARTS: Connecting Rod: Thrust in connecting rod – stress due to whipping action on connecting rod ends – Cranks
and Crank shafts, strength and proportions of over hung and center cranks– Crank pins, Crank shafts.
Pistons, Forces acting on piston – Construction Design and proportions of piston., Cylinder, Cylinder liners,
UNIT – III POWER TRANSMISSIONS SYSTEMS, PULLEYS: Transmission of power by Belt and Rope drives, Transmission
efficiencies, Belts – Flat and V types – Ropes - pulleys for belt and rope drives, Materials,Chain drives
SPUR & HELICAL GEAR DRIVES: Spur gears- Helical gears – Load concentration factor – Dynamicload factor. Surface
compressive strength – Bending strength – Design analysis of spur gears – Estimation of centre distance, module and face
width, check for plastic deformation. Check for dynamic and wear considerations.
UNIT –IV Design of power screws: Design of screw, Square ACME, Buttress screws, design of nut, compound screw, differential screw,
ball screw- possible failures.
Machine Tool Elements: Design of beds, slide ways, spindles- material selection, design of strength and rigidity of parts.
TEXT BOOK: 1. Machine Design, V.Bandari TMH Publishers
2. Machine Design, S MD Jalaludin, Anuradha Publishers
3. Machine Design, Kannaiah/ Scietech.
REFERENCES: 1. Design Data hand Book, S MD Jalaludin, Anuradha Publishers
2. Machine Design / R.N. Norton
3. Data Books : (I) P.S.G. College of Technology (ii) Mahadevan
4. Mech. Engg. Design / JE Shigley
5. Thermal Engineering – R.S. Khurmi & J.S.Gupta / S.Chand Pub.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Heat Transfer Course Code: ME 3427
L T P C
3 1 0 4
Course Objectives
The course content enables students to:
1. Identify the important and /or possible Heat Transfer modes in any physical system.
2. To provide students with an opportunity of direct experience of doing Heat Transfer calculation so that they can
understand the base of the principles and able to make a critical assessment of industrial environment
3. Experience with practical applications of Heat Transfer.
4. Apply the energy balance equation to Heat Transfer problems to calculate the rate for Heat Transfer for all physical
devices in all modes of Heat Transfer
Course Outcomes
At the end of the course students are able to: 1. Understand basic modes of heat transfer and compute temperature distribution in steady state and unsteady state heat
conduction
2. Analyze heat transfer through extended surfaces
3. Interpret and analyze free & forced convection heat transfer
4. Comprehend the phenomena and flow regimes of boiling and condensation
5. Understand the principles of radiation heat transfer
6. Apply LMTD and NTU methods to design heat exchangers
UNIT – I
Introduction: Modes and mechanisms of heat transfer – Basic laws of heat transfer.
Conduction Heat Transfer: General heat conduction equation in Cartesian, Cylindrical and Spherical coordinates.
One Dimensional Steady State Conduction Heat Transfer: Homogeneous slabs, hollow cylinders and spheres – overall heat
transfer coefficient – electrical analogy – Critical radius of insulation.
Systems with variable Thermal conductivity – systems with heat sources or Heat generation. Extended surface (fins) Heat
Transfer – Long Fin, Fin with insulated tip and Short Fin.
(16)
UNIT II
One Dimensional Transient Conduction Heat Transfer: Systems with negligible internal resistance – Significance of Biot
and Fourier Numbers - Chart solutions of transient conduction systems.
Convective Heat Transfer : Classification of systems based on causation of flow, condition of flow, configuration of flow and
medium of flow – Dimensional analysis as a tool for experimental investigation – Buckingham Pi Theorem and method,
application for developing semi – empirical non- dimensional correlation for convection heat transfer – Significance of non-
dimensional numbers, Concepts of Continuity, Momentum and Energy Equations.
(14)
UNIT-III
Forced convection:
External Flows: Concepts about hydrodynamic and thermal boundary layer and use of empirical correlations for convective
heat transfer -Flat plates and Cylinders.
Free Convection: Development of Hydrodynamic and thermal boundary layer along a vertical plate – Use of empirical
relations for Vertical plates and pipes.
Heat Transfer with Phase Change:
Boiling: – Pool boiling – Regimes, Calculations on Nucleate boiling, Critical Heat flux and Film boiling.
Condensation: Film wise and drop wise condensation - Film condensation on vertical and horizontal cylinders using empirical
correlations. (16)
UNIT IV:
Heat Exchangers:
Classification of heat exchangers – overall heat transfer Coefficient and fouling factor – Concepts of LMTD and NTU methods
- Problems using LMTD and NTU methods.
Radiation Heat Transfer:
Emission characteristics and laws of black-body radiation – Irradiation– laws of Planck, Wien, Kirchoff, Lambert, Stefan and
Boltzmann– heat exchange between two black bodies – concepts of shape factor – Emissivity – heat exchange between grey
bodies, radiation shields.
TEXT BOOKS :
1. Heat Transfer / HOLMAN/TMH
2. Heat Transfer – P.K.Nag/ TMH
REFERENCE BOOKS:
1. Fundamentals of Engg. Heat and Mass Transfer / R.C.Sachdeva / New Age International
2. Heat Transfer – Ghoshdastidar – Oxford University Press – II Edition
3. Heat and Mass Transfer –Cengel- McGraw Hill.
4. Heat and Mass Transfer – R.K. Rajput – S.Chand & Company Ltd.
5. Essential Heat Transfer - Christopher A Long / Pearson Education
7. Heat and Mass Transfer – D.S.Kumar / S.K.Kataria & Sons
8. Heat and Mass Transfer-Kondandaraman
9. Fundamentals of Heat Transfer & Mass Transfer- Incropera & Dewitt / John Wiley Pub.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Industrial Robotics Course Code: ME 3428
L T P C
3 1 0 4 Course Objectives
The course content enables students to:
The goal of the course is to familiarize the students with the concepts and techniques in robotic engineering, manipulator
kinematics, dynamics and control, chose, and incorporate robotic technology in engineering systems.
1. Make the students acquainted with the theoretical aspects of Robotics
2. Enable the students to acquire practical experience in the field of Robotics through design projects and case studies.
3. Make the students to understand the importance of robots in various fields of engineering.
4. Expose the students to various robots and their operational details.
Course Outcomes (Expected)
At the end of the course students are able to: 1. Understand basic parts and configurations of robotic systems.
2. Analyze robotic systems using forward and inverse kinematics.
3. Analyze robotic systems for dynamic performance using Lagrange –Euler and Newton-Euler formulations.
4. Develop a trajectory plan for a given application.
5. Understand actuators and feedback devices used in robotic systems.
UNIT – I
Introduction: Automation and Robotics, CAD/CAM and Robotics – An over view of Robotics – presentand future applications
– classification by coordinate system and control system.
Components of the Industrial Robotics: Function line diagram representation of robot arms, common types of arms.
Components, Architecture, number of degrees of freedom – Requirements and challengesof end effectors, determination of
the end effectors.
UNIT – II
Motion Analysis: Homogeneous transformations as applicable to rotation and translation – problems.
Manipulator Kinematics: Specifications of matrices, D-H notation joint coordinates and world coordinates, Forward and
inverse kinematics – problems.
UNIT – III
Differential transformation and manipulators, Jacobians – problems.Dynamics: Lagrange – Euler and Newton – Euler
formations – Problems.
Trajectory planning and avoidance of obstacles, path planning, Skew motion, joint integrated motion –straight line motion..
UNIT IV
Robot actuators and Feedback components: Actuators: Pneumatic, Hydraulic actuators, electric & stepper motors. Feedback
components: position sensors – potentiometers, resolvers, encoders – Velocity sensors.
Robot Application in Manufacturing: Material Transfer - Material handling, loading and unloading-Processing - spot and
continuous arc welding & spray painting - Assembly and Inspection.
TEXT BOOKS:
1. Industrial Robotics / Groover M P /Pearson Edu.
2. Robotic Engineering / Richard D. Klafter, Prentice Hall
3. Robotics and Control / Mittal R K & Nagrath I J / TMH.
REFERENCES:
1. Robotics / Fu K S/ McGraw Hill.
2. An Introduction to Robot Technology, / P. Coiffet and M. Chaironze / Kogam Page Ltd. 1983 London.
3. Robot Analysis and Intelligence / Asada and Slow time / Wiley Inter-Science.
4. Introduction to Robotics / John J Craig / Pearson Edu.
5. Robot Dynamics & Control – Mark W. Spong and M. Vidyasagar / John Wiley & Sons (ASIA) Pte Ltd.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Refrigeration and Air Conditioning Course Code: ME 3429
L T P C
3 1 0 4
Course Objectives
The course content enables students to: 1. Provide the basics of refrigeration cycles and performance calculations.
2. Provide the basics of air conditioning
3. Provide the knowledge on different refrigeration techniques
4. Provide the basic principles of psychrometry.
5. Develop knowledge on the different air conditioning components
Course Outcomes
At the end of the course students are able to: 1. Understand the principles and applications of refrigeration systems
2. Understand vapor compression refrigeration system and identify methods for performance improvement
3. Study the working principles of steam jet, vapor absorption, thermoelectric and vortex tube systems
4. Analyze air conditioning processes using principles of psychometry.
5. Evaluate cooling and heating load in an air conditioning system
6. Identify ecofriendly refrigerants and use P-H charts to evaluate the performance of refrigeration systems 7.
UNIT – I Introduction to Refrigeration: Necessity and applications – Unit of refrigeration and C.O.P.– Types of Ideal cycles of
refrigeration.
Air Refrigeration: Bell Coleman cycle and Brayton Cycle, Open and Dense air systems – Actual air refrigeration system
problems – Refrigeration needs of Air crafts.
Vapour compression refrigeration – working principle and essential components of the plant – simple Vapour compression
refrigeration cycle – COP – Representation of cycle on T-S and p-h charts – effect of sub cooling and super heating – cycle
analysis – Actual cycle Influence of various parameters on system performance – Use of p-h charts – numerical Problems.
UNIT II
System Components: Compressors – General classification – comparison – Advantages and Disadvantages.
Condensers – classification – Working Principles
Evaporators – classification – Working Principles
Expansion devices – Types – Working Principles
Refrigerants – Desirable properties – classification refrigerants used – Nomenclature – Ozone Depletion – Global Warming.
Vapor Absorption System – Calculation of max COP – description and working of NH3 – water system and Li Br –water (
Two shell) System. Principle of operation Three Fluid absorption system, salient features.
UNIT III
Steam Jet Refrigeration System – Working Principle and Basic Components.
Principle and operation of (i) Thermoelectric refrigerator (ii) Vortex tube or Hilsch tube.
Introduction to Air Conditioning: Psychometric Properties & Processes – Characterization of Sensible and latent heat loads –
– Load concepts of RSHF and ADP.- Problems
UNIT IV
Requirements of human comfort and concept of effective temperature- Comfort chart –Comfort Air conditioning –
Requirements of Industrial air conditioning, Air conditioning Load Calculations.
Air Conditioning systems - Classification of equipment, cooling, heating humidification and dehumidification, filters, fans and
blowers
TEXT BOOKS: 1. Refrigeration and Air Conditioning / CP Arora / TMH.
2. A Course in Refrigeration and Air conditioning / SC Arora & Domkundwar / Dhanpatrai
REFERENCES:
1. Refrigeration and Air Conditioning / Manohar Prasad / New Age.
2. Principles of Refrigeration - Dossat / Pearson Education.
3. Refrigeration and Air Conditioning-P.L.Bellaney
4. Basic Refrigeration and Air-Conditioning – Ananthanarayanan / TMH
5. Refrigeration and Air Conditioning – R.S. Khurmi & J.K Gupta – S.Chand – Eurasia Publishing House (P) Ltd.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Unconventional Machining Processes Course Code: ME 3430
L T P C
3 1 0 4 Course objectives :
The course content enables students to: 1. Identify the classification of modern machine processes.
2. Understand the mechanism of Abrasive jet machining, Water jet machining and abrasive water jet machine
3. Compare thermal and non-thermal processes
4. Understand the applications of plasma process for machine processes.
5. Complete understanding on modern machine processes
Course Outcomes
At the end of the course students are able to: 1. Understand the need and applications of modern machining processes.
2. Understand the working principle of modern machining process.
3. Select a suitable modern machining process for given applications.
4. Understand the working principle of advanced forming processes.
UNIT – I
INTRODUCTION – Need for modern machining methods-Classification of modern machining processes – considerations in
process selection, Materials and Applications
Ultrasonic machining – Elements of the process, mechanics of metal removal process parameters, economic considerations,
applications and limitations.
UNIT – II Abrasive jet machining, Water jet machining and abrasive water jet machine : Basic principles, equipments, process variables,
mechanics of metal removal, MRR, application and limitations. Magnetic abrasive finishing, Abrasive flow finishing,
ELECTRO CHEMICAL PROCESSES
Fundamentals of chemical, machining, advantages and applications- Chemical machining-principle- maskants –etchants-
Photochemical machining Thermo chemical machining.
Fundamentals of electro chemical machining, electro chemical grinding, electro chemical honing and deburring process, metal
removal rate in ECM, Tool design, Surface finish and accuracy economic aspects of ECM – Simple problems for estimation of
metal removal rate. Fundamentals of chemical, machining, advantages and applications. Electro stream drilling, Shaped tube
electrolytic machining.
UNIT - III THERMAL METAL REMOVAL PROCESSES: General Principle and applications of Electric Discharge Machining,
Electric Discharge Grinding and electric discharge wire cutting processes – Power circuits for EDM, Mechanics of metal
removal in EDM, Process parameters, selection of tool electrode and dielectric fluids, methods surface finish and machining
accuracy. Wire EDM, principle, applications.
Generation and control of electron beam for machining, theory of electron beam machining, comparison of thermal and non-
thermal processes –General Principle and application of laser beam machining – thermal features, cutting speed and accuracy
of cut.
UNIT-IV Plasma s – transferred and non-transferred types of PAM- Application of plasma for machining, metal removal mechanism,
process parameters, accuracy and surface finish and other applications of plasma in manufacturing industries.
HERFs- explosive forming, Electro hydraulic forming, magnetic pulse forming, hydrostatic extrusions.
TEXT BOOK:
1. Advanced machining processes/ VK Jain/ Allied publishers.
REFERENCES:
1. Modern Machining Process / Pandey P.C. and Shah H.S./ TMH.
2. Non-conventional machining- P.K.Misra Narosa publishers.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Operations Research Course Code: ME 3431
L T P C
3 1 0 4 Course objectives :
The course content enables students to: 1. Develop systematic approach to handle problems to design of electrical circuit etc; with a goal of maximizing the profit
and minimizing cost.
2. Understand the various optimization techniques such as classified optimization, linear programming. One dimensional
minimization methods, unconstrained optimization techniques, constrained optimization techniques and dynamic
programming.
3. Understand the necessary sufficient conditions for finding the solution of the problems in classical optimization.
4. Comprehend the numerical methods for finding approximate solution of complicated problems.
5. Apply methods like North West corner rule, least count method etc. to solve the transportation problem.
Course Outcomes:
At the end of the course students are able to:
1. Formulate a real time situation into a mathematical model.
2. Assign a right job to a right person using job sequencing.
3. Make right decisions in operations management using game theory, queuing theory and replacement analysis.
4. Solve non-linear problems using non-linear programming techniques.
5. Perform optimum problem solving using dynamic programming and simulation techniques.
OPERATIONS RESEARCH
UNlT-I Development – definition – characteristics and phases – types of models operation research models – applications.
ALLOCATION: Linear programming problem formulation – graphical solution – simplex mehod – artificial variables
techniques – two – phases method, big-m method – duality principle.
NONLINEAR PROGRAMMING: One-Dimensional Minimization: Unimodal function- Elimination methods- Unrestricted
search- Exhaustive search- Dichotomous search- Fibonacci method- Golden section method- Interpolation methods- Quadratic
interpolation method.
UNIT-II: TRANSPORTATION PROBLEM: Formulation –optimal solution, unbalanced transportation problem – degeneracy,
assignment problem – formulation –optimal solution – variants of assignment problem travelling salesman problem.
.
UNIT –III SEQUENCING – Introduction – flow – shop sequencing – n jobs through two machines – n jobs through three machines – job
shop sequencing – two jobs through ‘m’ machines
REPLACEMENT- Introduction – replacement of items that deteriorate with time – when money value is not counted and
counted – replacement of items that fail completely, group replacement.
UNIT –IV THEORY OF GAMES: Introducing – mini. Max(max.mini) – criterion and optimal strategy – solution of games with saddle
points – rectangular games without saddle points – 2 x 2 games – dominance principle –m x 2 & 2 x n games – graphical
method.
WAITING LINES: Introduction – single channel – poison arrivals – exponential service times – with infinite population and
finite population models – multichannel – poison arrivals – exponential service times with infinite population single channel
poison arrivals.
TEXT BOOKS:
1. Operations Research/S.D Sharma – Kedarnath
2. Introduction to O.R/Hiller & Libermann (TMH)
REFERANCE BOOKS:
1. Operations Research/A.M.Natarajan. P.Balasubramani, A. Tamilarasi/Pearson Education.
2. Operations Research Methods & Problems/Maurice Saseini, Arhur Yaspan & Lawrence Friedman
3. Operation Research /R.Pannerselvam, PHI Publications.
4. Operation Research/J.K Sharma/MacMilan.
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Instrumentation and Dynamics Lab Course Code: ME 3232
L T P C
0 0 3 2
Course Objectives:
The course content enables students to: Students are able to understand principles involved in the measurement and control of industrial processes. In particular,
students will be able to learn
1. understand principles involved in Calibration
2. Learn about the Temperature sensors (Thermocouples, RTD's, Thermistors, etc.)
3. Aware of Pneumatic and hydraulic pressure concepts
4. Balance the reciprocating mases
Course Outcomes:
At the end of the course students are able to:
1. Perform calibration on Pressure gauges, temperature detectors and LVDT.
2. Study the working and calibrate photo and magnetic pickups and seismic pickups.
3. Determine the critical speed using whirling of shaft.
4. Perform balancing of rotating masses.
5. Determine gyroscopic couple.
6. Analyze cam profile.
List of Experiments
1. Calibration of Pressure Gauges
2. Study and calibration of LVDT transducer for displacement measurement.
3. Calibration of thermocouple for temperature measurement.
4. Calibration of capacitive transducer for angular displacement.
5. Study and calibration of photo and magnetic speed pickups for the measurement of speed.
6. Study and use of a Seismic pickup for the measurement of vibration amplitude of an engine bed at various loads.
7. Study and calibration of McLeod gauge for low pressure.
8. Calibration of resistance temperature detector for temperature measurement
9. Study and calibration of a Rota meter for flow measurement.
10. Determination of critical Speed by using Whirling of Shaft
11. Balancing of Rotating Masses
12. Determination of Gyroscopic Couple
13. Cam profile Analysis
Department of Mechanical Engineering
B.Tech- 6th
Semester
SYLLABUS (Applicable for 2012-13 admitted batch)
Course Title: Heat Transfer Lab Course Code: ME 3233
L T P C
0 0 3 2 Course Objectives:
The course content enables students to: 1. Impart experimental experience in Heat Transfer Lab those support Mechanical Engineering.
2. provide students with an opportunity of direct experience of doing Heat Transfer Lab calculation so that they can
understand the base of the principles and able to make a critical assessment of industrial environment
3. Teach the students fundamentals in element of Heat Transfer & its applications. So as to identify, formulate and solve the
problems of Heat Transfer device designs.
4. Develop an idea about how to measure heat transfer coefficients/constant like h, emissivity, Stefan Boltzmann constants
for devices like metal rod, lagged pipe, etc.,
5. Encourage the students to understand importance energy conversation and make them to experience with practical
applications in Heat Transfer Lab.
Course Outcomes:
At the end of the course students are able to: 1. Apply the knowledge of heat transfer to perform experiments related to conduction heat transfer
2. Evaluate heat transfer coefficient in free and forced convection heat transfer situation
3. Determine fin efficiency and emissivity in respective experiments
4. Observe the phenomena of drop and film wise condensation
5. Evaluate the performance of heat exchangers in parallel & counter flow types
List of Experiments 1. Composite Slab Apparatus – Overall heat transfer co-efficient.
2. Heat transfer through lagged pipe.
3. Heat Transfer through a Concentric Sphere
4. Thermal Conductivity of given metal rod.
5. Heat transfer in pin-fin
6. Experiment on Transient Heat Conduction
7. Heat transfer in forced convection apparatus.
8. Heat transfer in natural convection
9. Parallel and counter flow heat exchanger.
10. Emissivity apparatus.
11. Stefan Boltzman Apparatus.
12. Heat transfer in drop and film wise condensation.
13. Critical Heat flux apparatus.
14. Study of heat pipe and its demonstration.