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Here is the syllabus

I C Engines &
Mechanical Measurements and Control
Production Process-III &
Theory of Machines- II&
Heat Transfer &
Business Communication and Ethics#
I C Engines &
Mechanical Measurements and Control
Production Process-III &
Theory of Machines- II&
Heat Transfer &
Business Communication and Ethics#
Metrology and Quality Engineering
Machine Design I &
Mechanical Vibrations &
Thermal and Fluid Power Engineering&
Mechatronics
Finite Element Analysis &
Metrology and Quality Engineering
Machine Design I &
Mechanical Vibrations &
Thermal and Fluid Power Engineering&
Mechatronics
Finite Element Analysis&

Mechanical Engineering Syllabus issued by Mumbai University
Program Structure for B E Mechanical Engineering
T. E. Mechanical -(Semester V)
Subject Code Subject Name Teaching Scheme
(Contact Hours) Credits Assigned
Theory Pract. Theory Pract. Total
MEC501 I C Engines & 4 2 4 1 5
MEC502 Mechanical Measurements and Control 4 2 4 1 5
MEC503 Production Process-III & 4 2 4 1 5
MEC504 Theory of Machines- II& 4 2 4 1 5
MEC505 Heat Transfer & 4 2 4 1 5
MEL5O1 Business Communication and Ethics # - 2$+2 - 2 2
Total 20 14 20 7 27
Subject Code Subject Name Examination Scheme
Theory Term Work Pract./oral Total
Internal Assessment End Sem.
Exam. Exam.
Duration
(in Hrs)
Test1 Test 2 Avg.
MEC501 I C Engines & 20 20 20 80 03 25 25 150
MEC502 Mechanical Measurements and Control 20 20 20 80 03 25 25 150
MEC503 Production Process-III & 20 20 20 80 03 25 -- 125
MEC504 Theory of Machines- II& 20 20 20 80 03 25 -- 125
MEC505 Heat Transfer & 20 20 20 80 03 25 25* 150
MEL5O1 Business Communication and Ethics # -- -- -- -- -- 50 -- 50
Total -- -- 100 400 -- 175 75 750

T. E. Mechanical -(Semester VI)
Subject Code Subject Name Teaching Scheme
(Contact Hours) Credits Assigned
Theory Pract. Theory Pract. Total
MEC601 Metrology and Quality Engineering 3 2 3 1 4
MEC602 Machine Design I & 4 2 4 1 5
MEC603 Mechanical Vibrations & 4 2 4 1 5
MEC604 Thermal and Fluid Power Engineering & 4 2 4 1 5
MEC605 Mechatronics 4 2 4 1 5
MEC606 Finite Element Analysis & 3 2 3 1 4
Total 22 12 22 6 28
Subject Code Subject Name Examination Scheme
Theory Term Work Pract./oral Total
Internal Assessment End Sem.
Exam. Exam.
Duration
(in Hrs)
Test1 Test 2 Avg.
MEC601 Metrology and Quality Engineering 20 20 20 80 03 25 25 150
MEC602 Machine Design I & 20 20 20 80 03 25 -- 125
MEC603 Mechanical Vibrations & 20 20 20 80 03 25 25*` 150
MEC604 Thermal and Fluid Power Engineering & 20 20 20 80 03 25 -- 125
MEC605 Mechatronics 20 20 20 80 03 25 -- 125
MEC606 Finite Element Analysis & 20 20 20 80 03 25 25 150
Total -- -- 120 480 -- 150 75 825


B. E. Mechanical-(Semester VII)
Subject Code Subject Name Teaching Scheme
(Contact Hours) Credits Assigned
Theory Pract. Theory Pract. Total
MEC701 Machine Design -II 4 2 4 1 5
MEC702 CAD/CAM/CAE & 4 2 4 1 5
MEC703 Mechanical Utility Systems 4 2 4 1 5
MEC704 Production Planning and Control 4 2 4 1 5
MEE701X Elective- I 3 2 3 1 4
MEP701 Project- I -- 6# -- 3 3
Total 19 16 19 8 27
Subject Code Subject Name Examination Scheme
Theory Term Work Pract./oral Total
Internal Assessment End Sem.
Exam. Exam.
Duration
(in Hrs)
Test1 Test 2 Avg.
MEC701 Machine Design- II 20 20 20 80 03 25 25 150
MEC702 CAD/CAM/CAE& 20 20 20 80 03 25 25 150
MEC703 Mechanical Utility Systems 20 20 20 80 03 25 -- 125
MEC704 Production Planning and Control 20 20 20 80 03 25 25* 150
MEE701X Elective -I 20 20 20 80 03 25 -- 125
MEP701 Project- I -- -- -- -- -- 50 -- 50
Total -- -- 100 400 -- 175 75 750

& Common with Automobile Engineering * Only ORAL examination based on term work and syllabus
B. E. Mechanical-(Semester VIII)
Subject Code Subject Name Teaching Scheme
(Contact Hours) Credits Assigned
Theory Pract. Theory Pract. Total
MEC801 Design of Mechanical Systems 4 2 4 1 5
MEC802 Industrial Engineering and Management 4 2 4 1 5
MEC803 Refrigeration and Air Conditioning 4 2 4 1 5
MEE802X Elective- II 3 2 3 1 4
MEP802 Project- II -- 12# -- 6 6
Total 15 20 15 10 25
Subject Code Subject Name Examination Scheme
Theory Term Work Pract./oral Total
Internal Assessment End Sem.
Exam. Exam.
Duration
(in Hrs)
Test1 Test 2 Avg.
MEC801 Design of Mechanical Systems 20 20 20 80 03 25 25 150
MEC802 Industrial Engineering and Management 20 20 20 80 03 25 -- 125
MEC803 Refrigeration and Air Conditioning 20 20 20 80 03 25 25 150
MEE802X Elective -II 20 20 20 80 03 25 -- 125
MEP802 Project- II -- -- -- -- -- 50 100 150
Total -- -- 80 320 -- 150 150 700

* Only ORAL examination based on term work and syllabus
# indicates work load of Learner (Not faculty) in VII and VIII semester for Project
University of Mumbai, Mechanical Engineering (Third and Final Year) Revised Course (Rev-2012) 6/113

Project –I and II: Students groups and load of faculty per week
Project Groups: Students can form groups with minimum 2 (Two) and not more than 4 (Four)
Faculty Load : In semester VII 1/2 hour per week per project group
In semester VIII 1 hour per week per project group
Each faculty is permitted to take (guide) maximum 4 (Four) project groups.
Course codes Elective I Course codes Elective II
MEE7011 Product Life Cycle Management (PLM) MEE8021 Micro Electro Mechanical Systems (MEMS)
MEE7012 Power Plant Engineering & MEE8022 Renewable Energy Sources
MEE7013 Energy Management MEE8023 Project Management &
MEE7014 Supply Chain Management & MEE8024 Business Process Reengineering
MEE7015 Computational Fluid Dynamics & MEE8025 Cryogenics
MEE7016 Advanced Turbo Machinery MEE8026 Automobile Engineering
MEE7017 Piping Engineering MEE8027 Process Equipment Design
MEE7018 Emission and Pollution Control MEE8028 Alternative Fuels
MEE7019 Operations Research MEE8029 Enterprise Resource Planning
MEE70110 Total Productive Maintenance (TPM) MEE80210 World Class Manufacturing &
MEE70111 Robotics MEE80211 Nanotechnology
MEE70112 Digital Prototyping for Product Design –I MEE80212 Digital Prototyping for Product Design –II


Module Detailed Contents Hrs.
01 Introduction
Heat engines; Internal and external combustion engines; Classification of I.C. Engines; Cycle of operations in four strokes and two-stroke IC engines and their comparative study; Scavenging and scavenging blowers, Air standard cycles and Fuel air cycles, Variable specific heat and its effects, Dissociation and other losses, Actual cycles, Deviation of actual engine cycle from ideal cycle 06
02 Spark Ignition Engines
A. Carburetors and fuel injection system in S I Engines :Theory of carburetion, Simple carburetor, Essential parts of modern carburetor, Types of carburetors, Types of fuel injection systems in S I engines, Continuous injection system, Timed injection system, Electronic Fuel-Injection systems (EFIs), Advantages and disadvantages of SI engine fuel injection system
B. Ignition Systems : Spark Plug and its requirements, Battery, Magneto, Electronic ignition systems
C. Combustion: Combustion phenomenon in SI Engines, Ignition delay, Flame propagation, Pressure-Crank angle diagram, Abnormal combustion, Auto ignition, Detonation and Knocking, Factors affecting combustion and detonation, Types of combustion chambers
12
03 Compression Ignition Engines
A. Fuel Injection Systems : Types i.e. Air injection systems, Airless/solid injection systems, Common rail, individual pump, distributor and unit injector etc, Injection pumps, Fuel injector, Types of nozzle, Electronically controlled unit fuel injection system, C I Engine Governors: necessity and characteristics
B. Combustion : Combustion phenomenon in C I engines, Stages of combustion, Delay period, Knocking, Pressure-Crank angle diagram, Factors affecting combustion and knocking, Types of combustion chambers
12
04 Engine lubrication : Types of lubricants and their properties, SAE rating of lubricants, Types of lubrication systems
Engine Cooling : Necessity of engine cooling, disadvantages of overcooling, Cooling systems and their comparison: Air cooling, Liquid cooling
Supercharging/Turbo-charging : Objectives, Effects on power output and engine efficiency, Methods, Types, Limits 08


05 Engine Testing and Performance: Measurement of Break Horse Power, Indicated Power, Fuel Consumption, Air flow, BMEP, Performance characteristic of SI and CI Engines, Effect of load and Speed on mechanical, indicated thermal, break thermal and volumetric efficiencies, Heat balance sheet
Exhaust Emissions: Exhaust gas analysis and methods, necessity, constituents, Air pollution due to engine exhaust, Pollution control devices and EURO, BHARAT standards
Fuels: SI and CI engine fuels, Rating of fuels, Non conventional fuels: CNG, LPG, Bio-fuels, Hydrogen, Alcohol etc 06
06 Alternative Potential Engines: Stratified charge engine, Wankel engine, Free-piston engine, Stirling engine, VCR engine, Dual fuel engines, Multi fuel engines
Modern Trends in I C Engines 04

List of Experiments
Part A: Study of physical systems in terms of constructional details and functions
1] 2 Stroke and 4 Stroke Engines
2] Carburetor.
3] Ignition system.
4] Fuel injection system.

Part B: Students shall perform at least 5 experiments from the list
1] Morse Test on petrol engine.
2] Speed Test on petrol or/and diesel engine.
3] Load Test on diesel engine (engines).
4] Heat Balance test on diesel or petrol engines.
5] Experimental determination of Air fuel ratio and volumetric efficiency of the engine
6] Exhaust Gas/Smoke analysis of S.I./ C.I. engines
7] Effect of Supercharging on Performance Characteristics of an engine

Term Work
Term work shall consist of minimum 6 experiments from the list out of which 4 must be actual trials on IC Engines and 1 case study/report (in group of not more than 3 students) on latest trends/developments in IC Engines
The distribution of marks for term work shall be as follows:
• Laboratory work (Experiments) : 15 marks
• Case Study/Report : 05 marks
• Attendance (Theory and Practical) : 05 marks

The final certification and acceptance of term work ensures the satisfactory performance of laboratory work and minimum passing in the term work.
Internal Assessment
Assessment consists of two tests out of which; one should be compulsory class test (on minimum 40% of curriculum) and the other is either a class test (on minimum 70% of curriculum) or assignment on live problems or course project.

Practical/Oral examination
1. Practical examination shall be conducted in a group of not more than 5 students. Examination shall be based on actual trials performed during the semester. Students are expected to actually take reading and plot the performance characteristics and comment.
2. Examiners are expected to evaluate results of each group and conduct oral based on the same
3. The distribution of marks for practical/oral examination shall be as follows:
i. Practical performance …… 15 marks
ii. Oral …… ………………. .10 marks
4. Students work along with evaluation report to be preserved till the next examination
Objectives
1. To impart knowledge of architecture of the measurement system
2. To deliver working principle of mechanical measurement system
3. To study concept of mathematical modelling of the control system
4. To Analyse control system under different time domain

Outcomes: Learner should be able to…
1. Identify and select proper measuring instrument for specific application
2. Illustrate working principle of measuring instruments
3. Explain calibration methodology and error analysis related to measuring instruments
4. Mathematically model and analyze system/process for standard input responses

Modules. Details Hrs.
01 1.1 Significance of Mechanical Measurements, Classification of measuring instruments, generalized measurement system, types of inputs: Desired, interfering and modifying inputs.
1.2 Static characteristics: Static calibration, Linearity, Static Sensitivity, Accuracy, Static error, Precision, Reproducibility, Threshold, Resolution, Hysteresis, Drift, Span & Range etc.
1.3 Errors in measurement: Types of errors, Effect of component errors, Probable errors. 08
02 2.1 Displacement Measurement : Transducers for displacement, displacement measurement, potentiometer, LVDT, Capacitance Types, Digital Transducers (optical encoder) , Nozzle Flapper Transducer
2.2 Strain Measurement : Theory of Strain Gauges, gauge factor, temperature Compensation, Bridge circuit, orientation of strain gauges for force and torque, Strain gauge based load cells and torque sensors
2.3 Measurement of Angular Velocity: Tachometers, Tachogenerators, Digital tachometers and Stroboscopic Methods.
2.4 Acceleration Measurement, theory of accelerometer and vibrometers, practical accelerometers, strain gauge based and piezoelectric accelerometers. 08
03 3.1 Pressure Measurement: Elastic pressure transducers viz. Bourdon tubes, diaphragm, bellows and piezoelectric pressure sensors, High Pressure Measurements, Bridge man gauge. Vacuum measurement: Vacuum gauges viz. McLeod gauge, Ionization and Thermal Conductivity gauges.
3.2 Flow Measurement: Bernoullis flowmeters, Ultrasonic Flowmeter, Magnetic flow meter, rotameter.
3.3 Temperature Measurement: Electrical methods of temperature measurement Resistance thermometers, Thermistors and thermocouples, Pyrometers.
3.3 Sensitivity analysis of sensor-influence of component variation, Signal conditioning: Amplifier, Conversion, Filtering, Impedance Buffering, Modulation / Demodulation, Linearization, Grounding and Isolation. 08


04 4.1 Introduction to control systems. Classification of control system. Open loop and closed loop systems.
4.2 Mathematical modelling of control systems, concept of transfer function, Block diagram algebra. 06
05 5.1 Transient and steady state analysis of first and second order system. Time Domain specifications. Step response of second order system. Steady-state error, error coefficients, steady state analysis of different type of systems using step, ramp and parabolic inputs. 06
06 Stability analysis
6.1 Introduction to concepts of stability. The Routh criteria for stability.
6.2 Experimental determination of frequency response, Stability analysis using Root locus, Bode plot and Nyquist Plots.
6.3 State space modeling.
6.4 Process control systems, ON-OFF control. P-I-D Control. 12

List of Experiments
1. Calibration of Displacement sensors like LVDT, Potentiometers etc.
2. Calibration of Pressure Gauges
3. Calibration of Vacuum Gauges
4. Torque measurement using strain gauges
5. Calibration of tachometers
6. Vibration Measurement & Calibration of Accelerometers.
7. Experiments on feedback control systems and servomechanisms
8. System Identification of any one of the sensor
9. Experiment on frequency response system identification
10. Experiment on transient state response of a control system.
11. Experiment on design of PID controller for a system.

(Design based experiments shall be encouraged using standard National Instrument/ texas instrument/ dSPACE Gmbh/ Arduino or any other platform)
Term Work
Term work shall consist of minimum 08 experiments (04 from the measurement group and 04 from the control group), assignments on each module.
The distribution of marks for term work shall be as follows:
• Laboratory work (Experiments) : 10 marks
• Assignments : 10 marks
• Attendance (Theory and Practical) : 05 marks


Practical/Oral examination
1. Experiment for the examination shall be based on the list of experiments mentioned in the term work.
2. The distribution of marks for practical/oral examination shall be as follows:
iii. Practical performance …… 15 marks
iv. Oral …… ………………. .10 marks
3. Evaluation of practical examination to be done based on the experiment performed and the output of the experiments during practical examination.
4. Students work along with evaluation report to be preserved till the next examination

Theory Examination
In question paper weightage of each module will be proportional to number of respective lecture hours as mention in the syllabus.
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Question number 1 will be compulsory and based on maximum contents of the syllabus
3. Remaining questions will be mixed in nature (for example, if Q.2 has part (a) from module 3 then part (b) will be from other than module 3)
4. Total four questions need to be solved.

References
1. Measurement Systems (Applications and Design) 5th ed.- E.O. Doebelin - McGraw Hill.
2. Mechanical Engineering Measurement - Thomas Beckwith, N.Lewis Buck, Roy Marangoni - Narosa Publishing House, Bombay.
3. Mechanical Engineering Measurements - A. K. Sawhney - DhanpatRai& Sons, New Delhi.
4. Instrumentation Devices & Systems - C.S. Rangan&G.R.Sarrna - Tata McGraw Hill.
5. Instrumentation & Mechanical Measurements - A.K. Thayal.
6. Control System Engineering: by Nagrath IJ. and Gopal .M., Wiley EasternLtd.
7. Modem Control engineering: by K.Ogata, Prentice Hall
8. Control systems: Dhanesh Manik, Cengage Learning
9. Automatic Control System, Benjamin Kuo, Prentice Hall
10. Control system theory with engineering applications, Lysherski, Sergey E, Springer
11. Instrumentation and Control System, W. Bolton, Elsevier
12. Experimental Methods for Engineers - J. P. Holman. - McGraw Hills Int. Edition.
13. Engineering Experimentation - E.O. Doebelin - McGraw Hills Int. Edition
14. Mechanical Measurements- S.P.Venkateshan, Ane books, India
15. Theory and Design for Mechanical Measurements, 3rd ed., Wiley
16. Control System Engineering: Norman Nise, John Wiley and Sons
17. Feedback Control System, Charles Phillips, R. D. Harbor

University of Mumbai, Mechanical Engineering (Third and Final Year) Revised Course (Rev-2012) 13/113


& Common with Automobile Engineering
Objectives
1. To study sheet metal forming as well as mechanical behavior of stress system in metal forming processes.
2. To develop capability to design jigs and fixtures.
3. To give exposure to Non-traditional machining operations.
4. To study concepts regarding modern manufacturing techniques like rapid prototyping, rapid tooling, agile manufacturing technologies etc.

Outcome: Learner will be able to..
1. Demonstrate understanding of sheet metal forming and various stress systems involved in metal forming operations.
2. Design jigs and fixtures for a given applications.
3. Get knowledge about non-conventional machining operations and its application areas.
4. Illustrate advanced concepts such as rapid prototyping and Agile manufacturing.

Module Details Hrs.
01 Introduction to High speed machines, special purpose machines, transfer line and other mass production machines. Types of automats and its tooling. 04
02 Sheet Metal Forming :
Elementary treatment of press working, Operation on presses, Press devices Classification of presses, Constructional features of blanking, piercing, compound, combination, progressive, bending, forming and drawing dies, Load calculations, development of blanks, scrap strip layout, punches, selection of die sets, stock guides, strippers, pilots, stops etc. selection of presses, capacities and other details. 10
03 Design of Jigs and Fixtures:
Need for jigs and fixtures, elements of Jigs and fixtures, principles of location, design of locating elements, locating pins support pins spring back, vee blocks, etc. principles of clamping simple hand operated clamps, like screw clamp, lever clamps and other types of clamps. Drill bushes-their types and applications indexing devices, auxiliary elements. Design of drill jigs like plate, leaf solid and box types for drilling combined with reaming, spot facing etc. design of milling fixtures such as plain, string, gang and indexing types. Design of turning fixtures. 12
04 Non-traditional Machining
Ultrasonic Machining (USM), Abrasive Jet Machining (AJM),Water Jet Machining, Electrochemical Machining (ECM),Chemical Machining (CHM)Electrical Discharge Machining (EDM),Plasma Arc Machining (PAM),Laser Beam Machining (LBM),Electron Beam Machining (EBM), Arc cutting processes and Oxy fuel cutting process. 08
05 Plastics Injection Mold Design: General arrangement of an injection mold, Basic systems of the mold – Feeding system, cooling system and ejection systems, Concepts of three plate molds and tooling for moulding articles with undercuts, Concepts of split molds, hot runner systems – Their advantages and limitation over conventional systems. Basic concepts of mold standardization and innovative mold components. 08


06 Agile Manufacturing Technologies:
Introduction, Developing agile manufacturing, Integration of Product/Process Development, Application of IT/IS concepts, Agile supply chain management, Design of skill and knowledge and Computer control of Agile manufacturing.
Flexible manufacturing systems. 06


Internal Assessment
Assessment consists of two tests out of which; one should be compulsory class test (on minimum 40% of curriculum) and the other is either a class test (on minimum 70% of curriculum) or assignment on live problems or course project.
Theory Examination
In question paper weightage of each module will be proportional to number of respective lecture hours as mention in the syllabus.
1. Question paper will comprise of 6 questions, each carrying 20 marks.
2. Question number 1 will be compulsory and based on maximum contents of the syllabus
3. Remaining questions will be mixed in nature (for example, if Q.2 has part (a) from module 3 then part (b) will be from other than module 3)
4. Total four questions need to be solved.

References
1. Mechanical Metallurgy, G E Dieter ,McGraw Hill.
2. Jigs and Fixtures, P H Joshi, Mc Graw Hill.
3. Production Technology, R C Patel & C G Gupte.
4. Production Technology, HMT, Tata Mc Graw Hill.
5. Introduction to Jigs and Tool design, HA Kempster, Butterworth Heinemann Ltd.
6. Manufacturing Process, R A Lindberg, PHI India.
7. Agile Manufacturing- Forging Mew Frontiers, Poul T Kidd,Amagow Co. UK.
8. Agile Manufacturing, AGunasekharan, the 21st Century Competitive strategy, Elsevier Press,India.
9. Stereo Lithography and other RP & M Technologies, Paul F.Jacobs: SME, NY 1996.
10. Rapid Manufacturing, Flham D.T &Dinjoy S.S Verlog London2001.
11. Fundamentals of modern Manufacturing, Fourth Edition, Mikell P Groover, John Wiley & Sons.
12. Metals handbook ,Forming and Forging, Vol. 14, ASM.

& Common with Automobile Engineering
Objectives
1. To acquaint with working principles of clutches and its constructional details.
2. To study working and types of brakes and dynamometers.
3. To acquaint with working principles and applications of gyroscope and governors.
4. To demonstrate different types of gear trains and its applications.

Outcomes: Learner will be able to…
1. Apply the working principles of clutches and its constructional details.
2. Analyze working of brakes and dynamometers.
3. Demonstrate working mechanism of different types of governors.
4. Analyze and select gear trains.
5. Analyze gyroscopic effect on various applications

Address:-
Mumbai University
CST Road, Kalina, Santacruz East, Mumbai, Maharashtra 400032

Phone:-
022 2654 3000

For full information buddy please go through the file;

Attached Files

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