ME 6th sem Computer Aided Engineering (CAE) syllabus RGTU/RGPV ME-607 Computer Aided Engineering (CAE) syllabus

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ME-607 Computer Aided Engineering (CAE) Syllabus

 RGTU/RGPV Computer Aided Engineering (CAE) SYLLABUS

Mechanical Engineering  ME 6th Semester Syllabus

Practical in CAD/CAM lab covering following topics:

Unit 1 Methods to solve engineering problems- analytical, numerical, experimental, their merits and comparison, discretization into smaller elements and effect of size/ shape on accuracy, importance of meshing, boundary conditions, Computer Aided Engineering (CAE) and design, chain-bumping-stages vs  concurrent-collaborative  design  cycles,  computer  as  enabler  for  concurrent  design  and  Finite Element Method (FEM), degree of freedom (DOF), mechanical systems with mass, damper and spring, stiffness constant  K  for tensile, bending and torsion; Practical applications of FEA in new design, optimization/ cost-cutting and failure analysis,

Unit 2 Types of analysis in CAE, static (linear/ non linear), dynamic, buckling, thermal, fatigue, crash NVH and CFD, review of normal, shear, torsion, stress-strain; types of forces and moments, tri-axial stresses, moment  of  inertia, how to do meshing, 1-2-3-d elements and length of elements; force stiffness and displacement  matrix, Rayleigh-Ritz and Galerkin FEM; analytical and FEM solution for single rod element and two rod assembly.

Unit 3 Two-dimension meshing and elements for sheet work and thin shells, effect of mesh density and biasing  in  critical  region,  comparison between  tria  and  quad  elements,  quality  checks,  jacobian, distortion, stretch, free edge, duplicate node and shell normal.

Unit 4 Three-dimension meshing and elements, only 3 DOF, algorithm for tria to tetra conversion, floating  and fixed trias, quality checks for tetra   meshing, brick meshing and quality checks, special elements and techniques, introduction to weld, bolt, bearing and shrink fit simulations, CAE and test data correlations, post processing techniques

Unit 5 Review of linear optimization, process and product optimization, design for manufacturing (DFM) aspects in product development, use of morphing technique in FEA, classical design for infinite life and design for warranty  life, warranty yard meetings and functional roles, climatic conditions and design abuses, case studies.

References:
1.  Gokhle Nitin; et al; Practical Finite Element Analysis; Finite to Infinite, 686 Budhwar Peth, Pune.
2.  Logan DL ; A First Course in Finite element Method; Cegage
3.  Krishnamoorthy; Finite Element Analysis, theory and programming; TMH
4.  Buchanan; Finite Element Analysis; Schaum series; TMH
5.  Seshu P; Textbook of Finite Element Analysis; PHI.
6.  Chennakesava RA; Finite Element Methods-Basic Concepts and App; PHI Learning
7.  Reddy JN; An introduction to finite element method; TMH
8.  Desai Chandrakant S et al; Introduction to finite element Method; CBS Pub
9.  Hutton D; Fundamentals of Finite Element Analysis; TMH
10. Zienkiewicz; The finite element Method; TMH
11. Martin and Grahm; Introduction to finite element Analysis (Theory and App.)
12. Rao, S.S., The Finite Element Method in Engineering; Peragamon Press, Oxford.
13. Robert DC., David DM et al, Concepts and Application of Finite Element Analysis; John Wiley.
14. Chandrupatla, T.R. an Belegundu, A.D., Introduction to Finite Elements in Engineering,PHI

ME 6th sem Heat & Mass Transfer syllabus RGTU/RGPV ME-605 Heat & Mass Transfer syllabus

Related: RGTU/RGPV Heat & Mass Transfer syllabus, RGTU/RGPV ME Heat & Mass Transfer syllabus, BE ME 6th semester Heat & Mass Transfer  Syllabus

 

ME-605 Heat & Mass Transfer Syllabus

 RGTU/RGPV Heat & Mass Transfer SYLLABUS

Mechanical Engineering  ME 6th Semester Syllabus

Unit-1 Basic Concepts: Modes of heat transfer, Fourier’s law, Newton’s law, Stefan Boltzman law; thermal resistance and conductance, analogy between flow of heat and electricity, combined heat transfer process; Conduction: Fourier heat conduction equation, its form in rectangular, cylindrical and spherical  coordinates, thermal diffusivity, linear one dimensional steady state conduction through a slab, tubes, spherical shells and composite structures, electrical analogies, critical-insulation-thickness for pipes, effect of variable thermal conductivity.

Unit  2 Extended surfaces (fins): Heat transfer from a straight and annular fin (plate) for a uniform cross   section;  error  in  measurement  of  temperature  in  a  thermometer  well,  fin  efficiency,  fin effectiveness,  applications; Unsteady heat conduction: Transient and periodic conduction, heating and cooling of bodies with known temperatures distribution, systems with infinite thermal conductivity, response of thermocouples.


Unit  3  Convection:  Introduction,  free  and  forced  convection;  principle  of  dimensional  analysis, Buckingham ‘pie’ theorem, application of dimensional analysis of free and forced convection, empirical correlations for laminar and turbulent flow over flat plate and tubular geometry; calculation of convective heat transfer coefficient using data book.

Unit 4 Heat exchangers: Types- parallel flow, counter flow; evaporator and condensers, overall heat transfers   coefficient,  fouling  factors,  log-mean  temperature  difference  (LMTD),  method  of  heat exchanger analysis, effectiveness of heat exchanger, NTU method;
Mass transfer:  Fick’s  law,  equi-molar  diffusion,  diffusion  coefficient,  analogy  with  heat  transfer, diffusion of vapour in a stationary medium.

Unit 5 Thermal radiation: Nature of radiation, emissive power, absorption, transmission, reflection and emission of radiation, Planck’s distribution law, radiation from real surfaces; radiation heat exchange between black and gray surfaces, shape factor, analogical electrical network, radiation shields. Boiling and condensation: Film wise and drop wise condensation; Nusselt theory for film wise condensation  on  a  vertical  plate  and  its  modification  for  horizontal  tubes;  boiling  heat  transfer phenomenon, regimes of boiling, boiling correlations.

RGTU/RGPV ME-605 Heat & Mass Transfer syllabus References:

1.  Sukhatme SP; Heat and mass transfer; University Press Hyderabad
2.  Holman JP; Heat transfer; TMH
3.  Nag PK; heat and Mass Transfer; TMH
4.  Dutta BK; Heat Transfer Principles And App; PHI Learning
5.  Mills AF and Ganesan V; Heat transfer; Pearson
6.  Cengel Yunus A; Heat and Mass transfer;TMH
7.  Yadav R; Heat and Mass Transfer; Central India pub-Allahabad
8.  Baehr HD;Stephan K; Heat and Mass Transfer; MacMillan Pub
9.  Incropera FP and Dewitt DP; Heat and Mass transfer; Wiley

RGTU/RGPV ME-605 Heat & Mass Transfer Suggested List of Experiments (Pl. expand it):

1 Conduction through a rod to determine thermal conductivity of material
2 Forced and free convection over circular cylinder
3 Free convection from extended surfaces
4 Parallel flow and counter flow heat exchanger effectiveness and heat transfer rate
5 Calibration of thermocouple
6 Experimental determination of Stefen-Boltzman constant

ME 6th sem Internal Combustion Engines syllabus RGTU/RGPV ME-604 Internal Combustion Engines syllabus

Related: RGTU/RGPV Internal Combustion Engines syllabus, RGTU/RGPV ME Internal Combustion Engines syllabus, BE ME 6th semester Internal Combustion Engines  Syllabus

 

ME-604 Internal Combustion Engines Syllabus

 RGTU/RGPV Internal Combustion Engines SYLLABUS

Mechanical Engineering  ME 6th Semester Syllabus

Unit I: Internal Combustion Engine: S.I. and C.I. engines of two and four stroke cycles, real cycle of SI and CI engines, determination of engine dimensions, speed, fuel consumption, output, analysis mean effective pressure, efficiency, factors effecting volumetric efficiency, heat balance, performance characteristics of SI and CI engines, cylinder arrangement, firing order, power balance for multi-cylinder engines, valve timing.

Unit II: Combustion in SI engines: Flame development and propagation, ignition lag, effect of air density, temperature, engine speed, turbulence and ignition timings, physical and chemical aspects of detonation, effect  of engine and fuel variables on knocking tendency, knock rating of volatile fuels, octane number, H.U.C.R.,  action of dopes, pre-ignition, its causes and remedy, salient features of various type combustion chambers, valve timing and firing order.

Unit III: Combustion in C.I. Engines: Times base indicator diagrams and their study, various stages of combustion, delay period, diesel knock, octane number, knock inhibitors, salient features of various types  of  combustion  chambers,  fuel,  ignition,  cooling,  exhaust  and  lubrication  systems;  Simple problems on fuel injection, various types of engines, their classification and salient features. Rotary I. C. engines, their principles of working.


Unit IV: I.C. Engine System: Fuels, ignition systems, cooling, exhaust/scavenging and lubrication system. Fuel metering in SI engine: Fuel injection in SI engine (MPFI & TBI), Theory of carburetion, simple problems on carburetion. Fuel metering in CI engines: Fuel injection in CI engine and simple problems, various types of engines, their classification and salient features. 

Fuels: Conventional fuels and alternate fuels, engine exhaust emission, carbon monoxide, un-burnt hydro carbon, oxides of nitrogen, smoke, density, measurement and control, hydrogen as alternate fuel.

Unit V: Supercharging: Effect of attitude on mixture strength and output of S.I. engines, low and high pressure super charging, exhaust, gas turbo-charging, supercharging of two stroke engines.

RGTU/RGPV ME-604 Internal Combustion Engines syllabus References:
1.  Ganeshan V; Internal Combusion engines; TMH
2.  Mathur ML & Sharma RP; A. Course in IC engines; DhanpatRai
3.  Gupta HN; Fundamentals of IC Engines; PHI
4.  Srinivasan S; Automotive Engines; TMH
5.  Halderman JD and Mitchell CD; Automotive Engines theory and servicing; Pearson
6.  DomKundwar; Internal Combustion Engines ; Dhanpat Rai Publications
7.  Taylor GF; Internal Combustion Engines Theory & Practice; MIT Press
8.  Richard Stone; Introduction to IC Engines; Society of Automotive Engr (Palgrave Mc Millan)

RGTU/RGPV ME-604 Internal Combustion Engines syllabus Suggested List of Experiments (Pl. expand it):
1.  Determination of Valve timing diagram
2.  Load test on Petrol Engine
3.  Heat Balance of SI engine
4.  Heat Balance of CI Engine
5.  Study of Battery Ignition system and Electronic Ignition System
6.  Study of Diesel fuel pump
7.  Study of Diesel fuel injectors
8.  Study of a Carburetors
9.  Study of Fuel Injection system in SI Engine 

10. Study of lubricating system in CI Engines

ME 6th sem Metal Cutting and CNC machines syllabus RGTU/RGPV ME-603 Metal Cutting and CNC machines syllabus

Related: RGTU/RGPV Metal Cutting and CNC machines syllabus, RGTU/RGPV ME Metal Cutting and CNC machines syllabus, BE ME 6th semester Metal Cutting and CNC machines Syllabus

 

ME-603 Metal Cutting and CNC machines Syllabus

 RGTU/RGPV Metal Cutting and CNC machines SYLLABUS

Mechanical Engineering  ME 6th Semester Syllabus

Unit  I:  Lathe: Classification  of  machine  tools  and  their  basic  components;  lathe-  specification, components & accessories, various operations on lathes, capstan & turret lathes, tool layout, methods of thread production, machining time, single point cutting tools, tool signature and nomenclature

Unit II:  Grinding: Types of grinding machines, surface, cylindrical and internal grinding, grinding wheels, specifications, wheel turning and dressing without eccentricity, centre-less grinding.

Unit III: Milling: Vertical, horizontal and universal type machines, specifications and classifications of milling machines, universal dividing head plain and different indexing, gear cutting, milling cutters. Drilling & Broaching:  Fixed spindle, radial and universal drilling machines, drilling time, broaching principle, broaches and broaching machines.

Unit IV: Shapers: Classification and specifications, principle parts, quick return mechanism, shaper operations,  speed feed, depth of cut, machining time. Surface qualities, equipment used for rating surfaces, rms. CLA value, causes for surface irregularities. Gear Cutting: Die casting, methods of forming gears, generating process, Gear shaping, gear shaving, gear grinding gear testing.


Unit V: Mechatronics: Introduction to control systems, analog control, transfer function, procedure for writing  transfer function, signal flow diagram, introduction to electronic components like switches, magnetic type, electromagnetic type, transducers and other sensors, servo motors, basics of CD-ROM players, PLC, applications, CNC machines.


RGTU/RGPV ME-603 Metal Cutting and CNC machines syllabus References:
1.  Rao PN; Manufacturing Technology vol I and II; TMH
2.  Hazra Chadhary; Workshop Tech.II; Media Promoter and Pub
3.  Lindberg RA; Processes and Materials of Manufacturing; PHI.
4.  Raghuvanshi;BS; Work shop technology Vol-I, II; Dhanpat Rai Delhi
5.  Alciatori DG, Histand MB; Introduction to Mechatronics and Measurement system; TMH
6.  HMT; Production Processes; TMH

RGTU/RGPV ME-603 Metal Cutting and CNC machines List of Experiment (Pl. expand it):

1. To make a complicate job on lathe machine with all operations like turning, step turning, drilling , tapper turning , thread cutting and knurling .
2. Study of center less grinding machine/ tool and cutter type grinding machine.
3. Study of horizontal/ universal milling machine, diving head and indexing mechanism of it.
4. To cut a spur gear on milling machine using rapid indexing method.
5. Study of radial drilling machine and preparing a job on it.
6. To study a sapping machine to learn about working of quick return mechanism.

ME 6th sem Power Plant Engineering syllabus RGTU/RGPV ME-602 Power Plant Engineering syllabus

Related: RGTU/RGPV Power Plant Engineering syllabus, RGTU/RGPV ME Power Plant Engineering syllabus, BE ME 6th semester Power Plant Engineering  Syllabus

 

ME-602 Power Plant Engineering Syllabus

 RGTU/RGPV Power Plant Engineering SYLLABUS

Mechanical Engineering  ME 6th Semester Syllabus

Unit I: Introduction to methods of converting various energy sources to electric power, direct conversion methods  renewable energy sources, solar, wind,  tidal, geothermal, bio-thermal, biogas and hybrid energy systems, fuel cells, thermoelectric modules, MHD-Converter.

Unit II: Fossil fuel steam stations: Basic principles of sitting and station design, effect of climatic factors on station and equipment design, choice of steam cycle and main equipment, recent trends in turbine and boiler sizes and  steam conditions, plant design and layout, outdoor and indoor plant, system components, fuel handling, burning systems, element of feed water treatment plant, condensing plant and  circulating  water  systems,   cooling  towers,  turbine  room  and  auxiliary  plant  equipment., instrumentation, testing and plant heat balance.


Unit III: Nuclear Power Station: Importance of nuclear power development in the world and Indian context,  Review of atomic structure and radio activity, binding energy concept, fission and fusion reaction, fissionable and fertile materials, thermal neutron fission, important nuclear fuels, moderators and coolants, their relative merits, thermal and fast breeder reactors, principles of reactor control, safety and reliability features.


Unit IV: Hydro-Power Station: Elements of Hydrological computations, rainfall run off, flow and power duration  curves, mass curves, storage capacity, salient features of various types of hydro stations, component  such  as  dams,  spillways,  intake  systems,  head  works,  pressure  tunnels,  penstocks, reservoir, balancing  reservoirs, Micro and pico hydro machines, selection of hydraulic turbines for power stations, selection of site.


Unit V: Power Station Economics: Estimation and prediction of load. Maximum demand, load factor, diversity factor, plant factor and their influence on plant design, operation and economics; comparison of hydro and nuclear power plants typical cost structures, simple problems on cost analysis, economic performance and  tariffs,  interconnected system and their advantages, elements of load dispatch in interconnected systems.

RGTU/RGPV ME-602 Power Plant Engineering syllabus References:

1-  Nag PK; Power plant Engg; TMH
2-  Al-Wakil MM; Power plant Technology; TMH
3-  Sharma PC; Power plant Engg; Kataria and sons, Delhi
4-  Domkundwar; Power Plant Engg; Dhanpatrai & sons.
5-  Rajput RK; A text book of Power plant Engg.; Laxmi Publications.
6-  Yadav R; Steam and gas turbine and power plant engg by