Bansilal Ramnath Agarwal Charitable Trust’s … cutting tools, speed, feed and depth of cut, Machining time calculations, Geometry of single point cutting tools, tool signature

Vishwakarma Institute of Technology Issue 01 : Rev No. 1 : Dt. 24/03/17

Structure and syllabus of S.Y. B.Tech. Industrial Engineering. Pattern A-16, A.Y. 2017-18 (P a g e | 1)

Bansilal Ramnath Agarwal Charitable Trust’s

Vishwakarma Institute of Technology (An Autonomous Institute affiliated to Savitribai Phule Pune University)

Structure & Syllabus of

B. Tech. (Industrial Engineering)

Pattern ‘A16’ Effective from Academic Year 2017-18

Prepared by: - Board of Studies in Industrial & Production Engineering



S.Y. B. Tech. Industrial Engineering AY 2017-18 (A16)

Module 3

Course Code Course Name

Contact Hours / Week Credits

Th. Proj. Based Lab

Regular Lab

Semester - I

S1 IP201THL Metal Cutting Processes 3 -- 2 4 S2 IP202THL Metrology & Mechanical

Measurements 3 -- 2 4

S3 MOOC

IP203TH Mathematics for Engineering Applications

3 -- -- 3

S4 IP204TLP Theory of Machines 3 2 -- 4 S5 IP205THP Strength of Machine Elements 3 2 -- 4

HSS HS202OPE Costing & Cost Control 2 -- -- 2 SD IP206SD Machine Drawing & GDT -- 2 -- 2

TOTAL 17 6 4 23 Semester - II

S1 IP225THL Casting & Welding Technology 3 -- 2 4 S2 IP226 THL Material Science 3 -- 2 4 S3 IP227TLP Design of Machine Elements 3 2 -- 4 S4 IP228TLP Thermal & Fluid Energy Conversion 3 2 -- 4

HSS HS201OPE Engineering and Managerial Economics

2 -- -- 2

S5 MOOC

IP229LTH Computer Graphics 2 2 -- 3

Proj IP230PRJ Mini Project -- 2 -- 2 TOTAL 16 8 4 23



FF No. : 654

Credits: 04 Teaching Scheme: - Th.3 + Lab 2 (Hrs/Week)

Unit I Metal cutting: (6 Hrs) Types of cutting tools, Mechanics of cutting and chip formation, orthogonal and oblique cutting, cutting forces, specific cutting energy and power requirements, cutting tool materials, tool wear and tool life, economics of machining, thermal aspects of machining, cutting fluids, machinability.

Unit II Lathe Machines and operations: (7 Hrs) Lathe – Types of lathe, lathe specifications, principal components, accessories and attachments, various operations on lathe (turning, boring, taper turning, thread cutting etc.), lathe cutting tools, speed, feed and depth of cut, Machining time calculations, Geometry of single point cutting tools, tool signature.

Unit III (7 Hrs) Reciprocating Machine tools, Drilling Machines and Related Operations: Shaper, Planer and slotting machines - Type of shapers, Planers and slotting machines, Quick return mechanism, shaper operations, cutting speed, feeds, machining time, Shaper vs. Planer Drilling Machines - Types and operations, boring tool, drills and reamers, cutting speeds and feeds, machining time.

Unit IV (7 Hrs) Milling Machines and operations Types of milling machines, up and down milling, milling operations, accessories, standard and special equipments, Universal dividing head, Types of indexing (direct, plain, compound, differential, angular), size, shape and materials of milling cutters, cutting speeds, feed and depth of cut, machining time.

Unit V (7 Hrs) Abrasive processes Grinding process, composition of grinding wheel, standard markings of grinding wheels, standard shapes of grinding wheels, Dressing of grinding wheels, Types of grinding machines grinding operations - cylindrical, internal, surface, Centreless grinding, Creep feed grinding Other finishing processes: Honing, lapping, super finishing, buffing, burnishing processes

Unit VI (6 Hrs) Gear Cutting, Thread cutting & Broaching Operations Gear Cutting - Forming & generation, gear cutting on milling, gear hobbing, gear shaping, gear shaving, lapping & grinding, various machines used for gear manufacturing. Broaching - types of broaches, broaching methods, cutting action, chip disposal, types of broaching machines, broaching speeds, application of broaching, advantages and limitations.

IP201THL :: METAL CUTTING PROCESSES



List of Project areas: List of Project 1. Turning: Introduction and demonstrations of different lathe operations such as

knurling, grooving, drilling, boring, reaming, threading etc. ,safety precautions Practical: One composite job involving the above mentioned operations. 2. Milling : Introduction, demonstration of milling operations such as plain milling, end

milling, gear cutting etc, safety precautions Practical: One job. Demonstrations 1. Demonstration on CNC lathe machine and grinding machine. Assignment: Process sheet of machining component. Text Books 1. Chapman W.A.J.; Workshop Technology : part 2; Fourth Edition, CBS publisher, 2. Choudhury S. K. ; Elements of Workshop Technology: vol II, Ninth Edition, Media

promoters and publishers pvt.ltd. Reference Books 1. Rao P.N., Manufacturing Technology 2, 2nd Edition, Tata McGraw hill education pvt.

Ltd. 2. R.L. Timings, Manufacturing Technology, Vol I&II, 3/e, Pearson Education 3. Chapman W.A.J Workshop Tecnnology; Volume I, II, III, ELBS. 4. Hajara choudhary S. K., Bose S. K.; Elements of Workshop Technology,; Volume I,

II, Asia Publishing House 5. Begeman; Manufacturing Processes 6. Roy A. Lindberg; Processes and Materials of Manufacture; Fourth Edition.; Prentice

Hall of India 7. Degarmo Black and Kohser; Material and Processes in Manufacturing; Eighth Edition;

Prentice Hall of India

Course Outcomes: Students will be able to: 1. Understand the fundamentals of metal cutting and Machine simple and composite job

involving few lathe and milling operations. 2. Understand basic construction and working of various Machine tools used for metal

removal processes 3. Select proper work and tool holding devices, attachments and accessories of a machine

tool and 4. Illustrate machining operations performed on various machine tools 5. Understand various tool geometries and select appropriate cutting tools to obtain

required finished component 6. Define process parameters like cutting speed, feed and depth of cut and evaluate

machining time for machining processes



FF No. : 654

IP202THL METROLOGY & MECHANICAL MEASUREMENTS

Credits: 4 Teaching Scheme: 03 Hours / Week

Unit 1: Introduction To Metrology (06 Hours) Introduction to Metrology, Precision, Accuracy, Errors in Measurement, Calibration. Linear Measurement: Standards, Line Standard, End Standard, Wavelength Standard, Classification of Standards, Precision and Non Precision Measuring instruments, Slip Gauges. Angular Measurement: Sine bar, Manufacture of slip gauges, Sine Center, Uses of sine bars, angle gauges

Unit 2: Limits, Fits And Tolerances (07 Hours) Meaning, Indian standards system for limits fits and tolerances, Cost – Tolerance relationship, concept of Interchangeability, Indian Standard System. Design of limits Gauges: Types, Uses, Taylor’s Principle, Design of Limit Gauges. Inspection of Geometric parameters: Straightness, Parallelism, Concentricity and Circularity.

Unit 3: Comparators & CMM (07 Hours) Uses, Types, Advantages and Disadvantages of mechanical comparators Optical, Electrical, Pneumatic Comparators. Inspection of Geometric parameters: Straightness, Parallelism, Concentricity and Circularity Co-ordinate Metrology – Co-ordinate Measuring Machines, Types, computerized CMM, CMM probes

Unit 4: Surface Finish Measurement & Interferometry (07 Hours) Surface Texture, Meaning of RMS and CLA values, Tomlison’s Surface Meter, Taylor- Hobson Surface Meter, Grades of Roughness, Specifications Interferometry: Introduction, Flatness testing by interferometry, NPL Flatness Interferometer Recent Trends in engineering Metrology- Optical measurement, LASER interferometers, LASER Telemetric system, Machine vision System, Introduction to CMM Inspection of Geometric parameters: Straightness, Parallelism, Concentricity and Circularity.

Unit 5: Screw & Gear Metrology (07 Hours) Screw Thread Metrology: External Screw Thread terminology, Floating Carriage Instruments, Pitch and flank Measurement of External Screw Thread. Gear Metrology: Spur Gear Parameters and their Inspection Methods, pitch & Tooth thickness measurement by various methods Measurement of pitch – Internal Thread, Measurement of gear tooth profile, Profile projector

Unit 6: Temperature, Strain, Force, Shaft Power Measurement (06 Hours) Transducers- Analog & digital transducers, types Pressure measurement- Mechanical & Electromechanical instruments/devices Velocity measurement—linear & angular velocity measurement Temperature Measurement – Non-electrical, Electrical & Radiation methods (pyrometry) Strain Measurement -Strain gauge – classification (metallic, semiconductor), gauge factor, properties of gauge wire, rosettes Force Measurement - Basic methods of force measurement, Strain gauges, LVDT Shaft power Measurement -Belt, Gear Dynamometer, Absorption Dynamometer.

List of Practicals (Any 10): 1. Linear measurements by precision measuring instruments 2. Angular measurements by sine bar 3. Dial Gauge calibration



4. Profile Projector for measurement of screw thread parameters and saw tooth parameter 5. Design of limit gauge 6. Measurement of roundness using Johanson’s comparator 7. Measurement of gear tooth parameters 8. Measurement of screw thread parameters using floating carriage micrometer 9. Surface finish measurement 10. Use of interferometer for study of various surfaces 11. Machine tool metrology- Alignment tests on Lathe Machine 12. Study of Toolmakers Microscope

Text Books:

1. Jain R.K. Engineering metrology 20th Edition Khanna Publishers 2000

2. Gupta. I.C. A text book of engineering metrology

7th Edition Dhanpat Rai and sons

2012

Reference Books:

1. K.W. B. Sharp

Practical Engineering Metrology

1st Edition

Pitman Publication

1966

2. ASTE Handbook of industrial metrology

1st Edition

Prentice hall of India ltd

1967

3. Galye G.N Metrology for engineers 5th revised edition

Cengage Learning EMEA

1990

Course Outcome: Students will be able to: 1. Measure length using line-graduated instruments, i.e. vernier calipers, micrometers etc. 2. Design Go and No Go gauges based on principles of limits, fits and tolerance and

effectively use of comparators of various types. 3. Use comparators and coordinate measuring machine, laser metrology and optical

projection comparators to record measurements of complex profiles with high sensitivity. 4. Apply knowledge of various instruments and methods to determine surface finish and

dimensions of industrial components. 5. Use effective methods of measuring screw threads and gear teeth parameters. 6. Apply knowledge of various instruments and methods to measure Temperature, Strain,

Force, and Shaft Power



FF No: 654

IP203TH:: MATHEMATICS FOR ENGINEERING APPLICATION Credits: 03 Teaching Scheme: Theory: 3 Hours / Week

Unit I : Linear Differential equations of higher order (6 Hrs) Higher Order Homogeneous & Non Homogeneous Linear Differential Equations with Constant Coefficients, Solutions by General operator and Variation of Parameters method, Euler – Cauchy Equation, Application of system of ordinary differential equations by Matrix method. System of linear differential equations. Unit II : Basics Statistics (6 Hrs) Basic preliminaries, Random Variable. Bernoulli ,Binomial & Poisson Distribution . measures of Central Tendency, Dispersion, Skewness & Kurtosis, Graphical Tools of Data Presentation – Histogram, Bar Chart, Pie Diagram, etc. Data Collection – Sources of Data Primary & Secondary. Applications in Industrial & Production Engg Unit III: Laplace Transform & Inverse Laplace Transform (08 Hrs) Introduction to Laplace Transform and its properties, Laplace Transform of Unit step function, Delta function. Introduction to Inverse Laplace Transform and its evaluation, Application of Laplace transform for solving system of differential equations. Unit IV : Fourier series (06 Hrs) Introduction to Fourier series, Complex Fourier series and frequency spectrum, Fourier integrals, Fourier cosine and sine transforms. Fourier transforms. Unit V:Applications of Partial Differential equations (6 Hrs) Classification of Partial Differential Equations. solution of pde by separation of variables The heat & Wave equations. The equation of Laplace, Laplace & Fourier series techniques for solving Partial Differential Equations. Unit VI: Vector Calculus (8 Hrs) Vector and scalar functions & fields, Derivative, Gradient of a scalar field, Directional derivative, Divergence and curl of a vector field, vector identities, Irrotational and solenoidal vectors and potential functions, line and surface integrals, Green’s, Stoke’s and Gauss theorems and applications to Engineering Problems. Applications to Fluid dynamics.

Text Books:

1. Erwin Kreyszig,

Advanced Engineering Mathematics,

Edition No8 ,

John Wiley and sons inc 2003

2. Dr. B.S. Grewal,

Higher Engineering Mathematics,

Edition No 38 ,

Khanna Publishers, Delhi. 2000.

Reference Books:

1. Thomas G. B. and Finney

Calculus& analytic Geometry

Edition No.,6

Wesley/Narosa, 1985

2. C. Ray Wylie, Louis C Barrett R

Advanced Engineering Mathematics

Edition No2 ,

McGraw-Hill Book Company, 2002

3. Michael Advanced Engineering Edition Prentice Hall



D.Greenberg, Mathematics, No.2 , International, 1998 4. Dennis G. Zill

and Michael R. Cullen,

Advanced Engineering Mathematics,

Edition No.2 ,

CBS New Delhi, 2000.

Course Outcomes: Students will be able to: 1. Acquire the knowledge of Linear Differential Equation, Partial Differential Equation

Laplace Transforms, Fourier Transform, Vector Calculus, Basic Statistics 2. To find solution of Linear Differential Equation, Laplace Transforms, Fourier Transform

of some standard function 3. Solve Linear Differential Equation, Partial differential equation using classical method,

Basic Statistics 4. Use of transform techniques for solving solving Linear Differential Equation, Laplace

Transforms, Fourier Transform 5. Modeling of physical system of Linear Differential Equation, Partial Differential

Equation Laplace Transforms, Fourier Transform, Vector Calculus, Basic Statistics 6. Analyze & interpret the physical system



FF No. : 654

IP204TLP: THEORY OF MACHINES

Credits: 04 Teaching Scheme: Theory 3 Hrs / Week+ Lab 2 Hrs / Week Unit 1: Simple Mechanism

(5 Hours)

Kinematic link, types of link, machine, structure, types of constrained motion, kinematic pair, classification of kinematic pairs, degrees of freedom, kinematic chain, mechanism, inversion, four bar chain and its inversion, single slider crank chain and its inversion and double slider crank chain and its inversions. Ackerman steering mechanism, Hooke’s joint.

Unit 2: Kinematic Analysis of Mechanisms: (Velocity and

Acceleration Analysis) (8 Hours)

Introduction, Motion of a link, velocity of a point on a link by relative velocity method, velocity in a slider crank mechanism, introduction, acceleration diagram for a link, acceleration of a point on a link by relative acceleration method, Klein’s construction.

Unit 3: Governors (7 Hours) Introduction, Function, types of governor, centrifugal governor, terms used in governor, types of centrifugal governors - Watt, Porter, Proell & Hartnell and Pickering governor, sensitivities of governor, stability of governor, isochronous of governor, hunting, effort and power of governor.

Unit 4: Cams and Followers (8 Hours) Introduction, applications, types of cams and followers, terms used in radial cams, analysis of motion of follower, displacement, velocity, and acceleration diagrams for various types of follower motions: uniform velocity, SHM, uniform acceleration and retardation, cycloidal motion, construction of cam profile for roller, knife edge ,flat faced followers and oscillating follower.

Unit 5: Spur Gear (7 Hours) Advantages and disadvantages of gear drive, classification of toothed wheel, terms used in gears, involute and cycloidal profile, condition for constant velocity ratio-law of gearing, length of path of contact, length of arc of contact, interference in involute gears, minimum number of teeth on the pinion in order to avoid interference, minimum number of teeth on the wheel in order to avoid interference.

Unit 6: Gear Trains (5 Hours) Types of gear trains- simple gear trains, compound gear trains, reverted gear trains, epicyclic gear trains. Introduction to types of belt drives.

List of Practicals: A) Experiments: 1. To determine the mass moment of inertia of a connecting rod using a compound pendulum method. 2. Verification of cam jump phenomenon. 3. To perform experiment on Watt Governors and to find speed, height of a Watt governor



and obtaining the graph of governor speed Vs height of governor. B) Drawing Sheets (3 sheets of ½ imperial size) : 1. Graphical solution of two problems on acceleration analysis using relative acceleration

method. 2. Graphical solution of problems on velocity and acceleration in mechanisms by Kleins

construction method. 3. To draw a cam profile for specific follower motion. List of Project areas (Any 3 from below): Project -1: Simple Mechanisms Project -2: Kinematic analysis of mechanisms Project -3: Governors Project -4: Cams and Followers Project -5: Spur Gear & Gear Trains

Text Books:

1. S.S.Ratan Theory of Machines 11th Tata McGraw Hill 2008 2. R.S.Khurmi,

J.K.Gupta Theory of Machines 14th S Chand Co. Delhi 2005

3. Ballaney P. L., Khanna

Theory of Machines and Mechanisms

3rd Khanna Publisher 1999

4. Sadhu Singh Theory of Machines 5th Pearson Education 2009

5. Ghosh Amitabh and Malik Ashok


5th Affiliated East-West Press

1998

6. V.P. Singh Theory of Machines 8th Dhanpat Rai Publishing

2004

Reference Books:

1. Shigley Joseph Edward and Vicker John Joseph


5th Oxford University Press

2016

2. Thomas Bevan Theory of Machines

1st Pearson Education Ltd.

2016

3. Abdullah Shariff Howard L. Harrison

Theory of Machines

3rd Dhanpat Rai Publishing

1981

4. V.K.Bansal Theory of Machines

3rd Laxmi Publications Pvt Limited

2006

Course Outcomes: The student will be able to – 1. Classify different types of links and mechanisms used for different purposes in different

machines. 2. Draw velocity and acceleration diagrams of various mechanisms. 3. Analyze different types of governor. 4. Construct cam profile for the specific follower motion. 5. Understand the mechanism of spur gear and identify the various types of gears. 6. Understand the mechanism of gear trains and distinguish between various gear trains.



FF No.: 654

IP205THP:: STRENGTH OF MACHINE ELEMENTS

Credits: 04 Teaching Scheme: 3 Hrs / Wk + 2 Hrs/ Wk Project Prerequisite: Nil

Unit 1: Stress and Strain (8 Hours) Introduction and Review: Equilibrium of a Deformable Body, types of forces, types of support and reaction offered, Coplanar Loadings, Equations of Equilibrium, Numerical to find internal loading/support reactions/forces on a given structure. Geometric Properties of an Area: Centroid, use of parallel & perpendicular axis theorems to find moment of inertia of composite areas, polar moment of inertia, radius of gyration Internal forces developed in structural members ,Concept of types of actions and corresponding stresses (axial loading, bending, shear, torsion), units of stress, Saint-Venant’s Principle, Average Normal Stress and average shear stress followed by numerical, Stress on an Oblique plane under axial loading, stress under general loading conditions, Design consideration with numerical (Ultimate stress, allowable stress, Factor of safety) Hooks law of elasticity and Hooks law of shear, Normal strain, shear strain, Elastic Deformation of an Axially Loaded Member followed by numerical, AFD, Poisson’s Ratio , Generalized Hooks law, Bulk modulus

Unit 2: Torsion of circular section (5 Hours) Torsional deformation of a circular determinate shaft, shear stress and angle of twist, Torsion Formula, Absolute Maximum Torsional Stress, TMD, Power Transmission, Constant Torque and Cross-Sectional Area, Multiple Torques, Design of solid circular and tubular shaft, followed by numerical.

Unit 3: Shear Forces and Bending Moments (7 Hours) Concept of Shear and bending Moment Diagrams, Sign Convention, Numerical to draw SFD & BMD of Simply supported, Cantilevered ,and Overhanging beams subjected to various loading , Relation among load, shear and bending moment, concept of graphical methods to draw SFD & BMD

Unit 4: Stresses in Beams (6 Hours) Bending Stresses: Pure Bending and Nonuniform Bending, Deformation of a Straight member, Application of Flexure Formula Transverse Shear Stress: Shear in Straight Members, Shear stress Formula, Numerical to find shear stress and its distribution. Design of prismatic Beams for given bending and shear stress.

Unit 5: Transformation of stress (8 Hours) Concept of General state of stress and Plane stress, Sign Convention, Orientation of element, General Equations of Plane-Stress on inclined plane followed by numerical, Principal stresses and maximum shear stresses, Mohr’s Circle of plane Stress with numerical Theories of Failure: For Ductile Materials (Maximum-Shear-Stress and Maximum-Distortion-Energy Theory),Brittle Materials(Maximum-Normal-Stress Theory), Mohr’s Failure Criterion.



Unit 6: Applications of Plane Stresses (6 Hours) Stresses in thin walled pressure vessels, Principal Stresses in a Beam, Design of Transmission Shafts, Stresses under Combined Loadings

List of Project areas: Student will do exercises related to the subject in a small group, based on ANY ONE of the following activity 1. Making of three different demonstration models from any three different units, based

on concept or problems in mechanics of materials 2. Making of one model based on concept or problems from any unit along with its

mechanism of validation of results/measurements. 3. Development of any one virtual experiment in mechanics of materials 4. Writing and publishing one research paper in the field of mechanics of materials 5. Completion of one MOOC (massive open online course) along with its certification, in

mechanics of materials. 6. Develop video lecture of 60 minutes on any one topic listed below: Transformation of Plane Strain , Mohr’s Circle for Plane Strain, Columns, Deflection of Beams, strain energy, Thick wall pressure vessels, Bending of Curved members.

Text Books:

1. Ferdinand P. Beer, E. Russell Johnston

Mechanics of Materials

Edition No. 5th or 6th

McGraw-Hill education

2012

2. R. C. Hibbler Mechanics of Materials

8th or 9th Pearson Prentice Hall

2011

3. James and Gere Mechanics of Materials

5th /6th Thomson Learning, Inc

2004

Course Outcomes: Students will be able to: 1. Calculate normal stress, shear stress, and deformation and applications of the analysis and

design of members subjected to an axial load or direct shear 2. Analyze and design circular determinate shafts subjected to torsional loading for its shear

stress distribution and angle of twist. 3. Establish the shear force and bending moment diagrams for a beam 4. Determine bending and transverse shear stress in homogeneous beam having prismatic

cross section and design beam for a given bending moment and shear force. 5. Determine stress components by analytical and Mohr’s circle method ,for a plane state

of stress and to obtain the maximum normal and maximum shear stress along-with orientation of elements.

6. Analyze stresses developed in thin-walled pressure vessels. and to calculate resultant plane stresses in thin pressure vessels, beam and circular shafts subjected to combined loading(axial, bending, torsion)



FF No. : 654

Credits: 02 Teaching Scheme: - Theory 2 Hrs/Week

Unit I (07 Hrs) Cost Cost, Cost Centre. Cost Unit. Cost Allocation: Cost Accumulation and Apportionment. Elements of Cost: Material Cost. Different methods of pricing of issue of materials – LIFO, FIFO, HIFO, Weighted Average; Labour Cost: Direct & Indirect Different methods, Direct Expenses: Constituents and Significance. Accounting for Prime Cost. Unit II (07 Hrs) Overheads

Classification: Production, Office & Administration, Selling & Distribution. Treatment of Overheads: Collection of Overheads - Criteria, Primary and Secondary Distribution of Overheads: Step Method, Reciprocal Method, Repeated Distribution Method. Absorption of Overheads: Machine hour, labour hour rate. Preparation of Cost Sheet & Cost Statement

Unit III (8 Hrs) Costing Methods

Job Costing, Unit Costing, Contract Costing, Process Costing. Simple numerical on various methods of costing to enable ascertain cost of product. Standard costing: Concept, Standard Cost, Development and Use of standard costing. Calculation of Variance Numerical on calculation of variances. Variance – Variance Analysis. Material variance, Labour Variance, Overhead Variance Unit IV (07 Hrs) Activity Based Costing & Transfer Pricing

Concept, Concept of Cost Drivers. Calculation of Costs. Mechanism of Activity Based Costing. Transfer Pricing: Objective, Methods – Cost Based, Market Prices Based, Negotiated Prices. Recommended procedure for Transfer Pricing. Limitations of Traditional Costing

Total Contact Hours: 28 Text Books : 1. Prasad N. K.; Cost Accounting; Book Syndicate Pvt. Ltd., Calcutta 700 009 2. Bhattacharya A. K., Principles and Practice of Cost Accounting, Prentice Hall India 3 B K Bhar, Cost Accounting – Methods and Problems, Academic Publishers Reference Books : 1. Colin Drury, Management and Cost Accounting, English Language Book Society,

Chapman and Hall London. 2. Khan M. Y., Jain P. K., Financial Management, Tata McGraw Hill

HS202OPE : COSTING AND COST CONTROL



Course Outcomes: 1. Classify different types of costs and apply it for ascertainment of costs of a product or a

process 2. Understand and apply distribution of overheads to ascertain the cost of any product or

service. 3. Apply different types of costing methods and techniques according to the suitability for

various production processes and services. 4. Understand and apply the concept of activity based costing for cost ascertainment



FF No. : 654

IP206SD MACHINE DRAWING & GDT


List of Practicals:

1. Sketches of Conventional Representation of Machine Components as per ‘IS Code SP 46’ of Screw Threads, Tapped Holes, Holes on Circular Pitch, Countersunk and Counter-bores,

2. Sketches of Conventional Representation of Machine Components as per ‘IS Code SP 46’of Bearing, Splined Shafts, Tapers, Chamfers, Knurling, Keys

3. Sketches of Conventional Representation of Machine Components as per ‘IS Code SP 46’of Springs, Gears, Welded Joints, Structural Sections

4. Sketches of Conventional Representation of Machine Components as per ‘IS Code SP 46’of Types of Screws

5. Sketches of Conventional Representation of Machine Components as per ‘IS Code SP 46’of Bolts and Nuts

6. Sketches of Conventional Representation of Machine Components as per ‘IS Code SP 46’of Nut Locking Arrangements

7. 2 assembly drawings for each student as a project. Text Books:

1. P.S.Gill A Text Book of Machine Drawing

Revised Edition S K Kataria & Sons, New Delhi

2011

2. Cogorno, Geometrical Dimensioning & Tolerancing –

2nd Edition McGraw Hill. 2009

Reference Books:

1. K.L.Narayana, P. Kannaiah, K. Venkatata Reddy

Machine drawing

4th Edition

New Age International Pvt Ltd Publishers

2009

2. N.D.Bhatt, V.M.Panchal

Machine Drawing

49th edition

Charotar Publishing House Private Limited

2014

Course Outcomes:- The student will be able to – 1. Use BIS conventions in machine drawings 2. Sketch the various machine components 3. Read and interpret the given production drawings 4. Understand significance of assembly and detail drawings. 5. Draw Assembly and Details of Machine Components based on Theory of Geometrical

Dimensioning & Tolerancing



FF No. : 654

IP225THL::CASTING AND WELDING TECHNOLOGY Credits: 4 Teaching Scheme: (3h Theory + 2h Lab)Hours / Week

Unit 1: Foundry Industry, Patterns and Molds (7 Hours) Introduction of Casting as a manufacturing process, Classification of casting processes, applications and advantages and limitations of casting process, Classification of foundries based on different criteria, Major activities in foundry Foundry process flowchart and different layouts of foundry. Introduction to different ferrous and non-ferrous cast alloys and their applications, Patterns: Pattern materials, allowances, types of pattern, pattern design, Pattern color codes. Types of molding sand, properties of molding sands sand mold, molding sand materials, composition of molding sand Green and dry sand molding process. hand molding and machine molding, ramming methods, CO2 molding process. Unit 2: Core making and melting practice (6 Hours) Cores- Core sands, core sand composition, Functions of cores, types of cores and core boxes. Core making procedure, core prints, chaplets, Shell molding and core making, forces on cores and molds Melting of Metals, Types of melting furnaces, Cupola and induction melting furnaces construction and working, Charge calculation for cast Iron. Composition, physical properties and applications of ferrous and non-ferrous castings: Grey cast iron, S.G. iron, White cast iron, malleable cast iron, Aluminum copper and magnesium based alloys. Importance and methods of inoculation in cast irons, Degassing and modification treatments in aluminum, copper and magnesium alloy castings. Ladles – Types, Use, Lining materials. Unit 3: Methoding of casting and special casting techniques (7 Hours) Gating and Risering: Components of gating system, functions and importance, design parameters of gating. Gating ratio, pressurized and un-pressurized gating systems. Risers, functions and modulus. Directional solidification, use importance of chills and ceramic bricks. Yield of castings. Numerical treatment to be given to design of and gating system and riser design. Fettling and cleaning of castings, Defects, inspection and testing of castings. Special casting Processes: Gravity die casting, high Pressure die casting and low pressure die Casting, centrifugal casting, continuous casting, investment casting, their typical applications, merits and limitations. Pollution and safety in foundry: Possible hazards in foundries, Safety measures, Safety devices Types and sources of pollution in foundries, Measures for pollution control. Unit 4: Gas welding/cutting, soldering and brazing (7 Hours) Introduction, classification of Welding processes. Comparison with other joining processes, advantages, disadvantages, practical applications. Welding Symbols. Basic & supplementary weld symbols, types of weld Joints, Selection of Weld Joint, edge preparation Principle of operation, types of flames, Gas welding Techniques, filler material and fluxes, Gas welding equipments, advantages and applications, Gas cutting: merits, limitations and applications of above processes. Brazing, braze welding and soldering processes, merits, limitations and applications of above processes. Brazing and soldering fluxes, Filler metals & fluxes, Fusion welding defects.



Unit 5: Electric arc and resistance welding processes (6 Hours) Electric Arc welding processes-Power source, types of electrodes, coding of electrodes, Carbon arc, submerged arc, tungsten inert Gas (TIG), metal inert gas (MIG), electro slag welding process, plasma arc welding process - theory, comparison on merits, limitations and applications. Resistances Welding: Definition, Fundamentals, variables advantages and application, Spot Welding, Heat Shrinkage, Heat Balance Methods, Equipment, Electrodes, Seam, Projection Butt (up sets and flash), Percussion Welding – Definition, Principle of Operation, equipment, Metal Welded, advantages and application. Unit 6: Welding metallurgy, weldability and special welding techniques (7 Hours) Welding Metallurgy: Weld zone, Heat affected zone (HAZ) Weldability: Definition, effect of alloying elements, Purpose and types of tests, Hot Cracking, Root Cracking and Cold Cracking Tests. Welding Distortion: Concept of distortion, Types of distortion, Control of welding distortion Special welding techniques: Ultrasonic welding, Explosive Welding, Friction welding, Friction stir welding, Thermit welding, Laser welding, Electron beam welding. Inspection and Testing of Welds, Weld Defects: Common Weld defects, Causes and remedies of defects. List of Practicals: (Perform any 10 experiments) 1. Preparation of green sand with additives. 2. Preparation of cylindrical green sand samples by rammer block 3. To determine compatibility of green sand. 4. Permeability testing of green sand. 5. Grain size distribution and estimation of AFS no of system sand and silica sand. 6. Measurement of green compression and green shear strength of sand. 7. Mold hardness and core hardness measurement. 8. Design of cope, drag pattern and core box. 9. Estimation of gating ratio and casting yield. 10. Hand molding, melting of Al and casting of simple gear blanks. 11. Demonstration of welding machines TIG/MIG/resistance Spot welding 12. Weldability test of welded joint. 13. Metallurgical analysis of welded joint. Text Books: 1. P. N. Rao; Manufacturing Technology: Foundry, Forming & Welding; Tata McGraw Hill. 2. P.L. Jain; Principles of Metal casting; Tata McGraw Hill 3. O.P. Khanna; Foundry Technology; Khanna Publisher 4. O.P. Khanna; Welding Technology; Khanna Publisher Reference Books: 1. T.V.Rama Rao; Metal Casting: Principles & Practice; New Age International Pvt. Ltd. 2. P. C. Mukharjee; Fundamentals of Metal Casting; Oxford & IBH Publishing Co 3. Heine, Loper, Rosenthal; Principles of Metal Casting; Tata McGraw Hill 4. Richard Little; Welding & Welding Technology, Tata McGraw Hill 5. Dr. R. S. Parmar; Welding Processes and Technology; Khanna Publisher



Course Outcomes: The student will be able to – 1. Select and design and perform different pattern and mould making to manufacture

castings. 2. Understand and apply different methods of core making and melting techniques. 3. To design gating system and select appropriate casting method for manufacturing

castings with optimum cost and quality. 4. Apply fundamentals of gas welding, soldering and brazing techniques for joining of

appropriate material and job. 5. Understand and apply electric arc and resistance welding and nonconventional

techniques. 6. To test and analyze weld quality by mechanical properties and microstructural analysis.



FF No. : 654

IP226THL:: MATERIAL SCIENCE


Unit 1: Introduction to engineering materials and Plastic (06 Hours) Introduction to Material Science .Classification of Engineering Materials. Important properties of each group & some typical applications of each group., Structures and their property relationship in relation to engineering materials. Indexing of planes and directions. Plastic deformation - Mechanisms. Deformation of Single crystal and Polycrystalline materials. Numerical based on it. Imperfections in crystals. Dislocations, work hardening. Cold and Hot working of metals. Future Trends in Material Unit 2: Material Testing (7 Hours)

Destructive Testing – Tension test-Engineering and True Stress - True strain curves, conversion Relationships, Evaluation of properties. Numericals based on Tension Test. Engineering stress - Strain curves of different materials. Compression Test, Cupping Test on Sheet metal, Hardness Tests – Brinell, Poldi, Vickers, Rockwell Shore scleroscope, Durometer, Moh's test, Micro hardness test and hardness conversions. Impact tests, Fatigue and Creep tests. Non-destructive tests - Visual Inspection, Magna flux test Dye penetrant test, Sonic and Ultrasonic test, Radiography. Examples of selection of NDT & mechanical testing methods for selected components like crankshafts gears, razor blades, welded joints, steel and cast iron castings, rolled products, forged products.

Unit 3: Equilibrium diagrams (07 Hours) Related terms and definitions. Hume Rothery's rule of solid solubility. Gibb's phase rule. Polymorphism, Solidification, Dendritic growth. Cooling curves, Plotting of equilibrium diagrams, Lever rule, Isomorphous system. Coring. Eutectic systems, Partial eutectic systems. Uses of eutectic alloys. Layer type system, other transformation, non-equilibrium cooling and its effects. Numericals based on it. Practice of numerical based on equilibrium diagrams

Unit 4: Strengthening Mechanisms and Pyrometry (07 Hours) Strengthening Mechanisms: Refinement of grain size, Solid solution hardening, Dispersion hardening, Age hardening, Martensitic transformation etc Principle, Operation and uses of various pyrometers like thermocouples, Resistance pyrometer, Disappearing filament pyrometer, Total radiation pyrometer. Unit 5: Powder Metallurgy and Composite Materials (07 Hours) Powder Metallurgy: Process in brief, important powder characteristics, major powder manufacturing methods, Advantages and limitations of Powder Metallurgy Production details of some common Powder Metallurgy parts like self lubricated bearings Cemented carbide tools etc Composite materials: basic types, Properties , Applications



Unit 6: Corrosion Prevention and methods of Surface Improvements (06 Hours) Corrosion Prevention Methods: Preparation of substrate for surface engineering. Design and material selection, atmosphere control, Inhibitors, Cathodic and anodic protection, Coatings etc. Methods of surface improvement --- Electroplating, Surface Modification Techniques such as Electro deposition (Conventional electroplating, Electro less plating, Anodising, Diffusion coatings like Plasma nitriding, Aluminizing, Boronising, Chromizing , Vapour deposition conventional PVD and CVD, Diamond like coating, Electron beam PVD, Thermal Spray Coatings, Ion implantation etc.

List of Practicals: 1. Non destructive tests 2. Brinell hardness test on different materials 3. Vickers hardness test on different materials 4. Rockwell hardness test on different materials 5. Poldi hardness test on different materials 6. Compression test on brass 7. Erichsen cupping test on different sheet metals. 8. Impact test on Steel & Aluminium specimens 9. Tension test 10. Effect of cold working on hardness . Text Books:

1. V.D. Kodgire, Material Science and Metallurgy for Engineers, Everest Publishing House, Pune.

2. Smith W.F, Principles of Material Science and Engineering, McGraw Hill Book Co. 3. The science and engineering of materials, D. Askeland and P.P. Phule, 4th Edition,

Thomson learning Inc. Reference Books: 1. Davis H. E., Troxell G.E. and Wiskocil C. T., Testing of Engineering Materials. Mc

Graw Hill Book Co. 2. Van Vlack L.H., Elements of Material Science, Addison- Wesley Publishing Co. 3. Baldev Raj,T. Jayakumar and M. Thavsimuthu, Practical Non-Destructive Testing,

Narosa Publishing House. Delhi. 4. Hull and T. W. Clyne: An introduction to Composite Materials: Second Edition

Cambridge Solid State Science Series. Course Outcomes: The student will be able to – 1. Correlate crystal structures, crystallographic directions and planes, Plastic deformation

mechanisms, Cold & hot working changes in properties & with mechanical, physical, electrical & thermal properties

2. Apply and integrate knowledge of properties and performance to solve materials selection and design problems.

3. Apply and integrate knowledge of equilibrium diagram 4. Apply and integrate knowledge of strengthening mechanisms & Pyrometry 5. Apply and integrate knowledge of Powder Metallurgy & Composite materials 6. Apply and integrate knowledge of apply and integrate knowledge of various surface

modification techniques.



FF No. : 654

IP227TLP DESIGN OF MACHINE ELEMENTS

Credits: 04 Teaching Scheme: 3 Hours / Week, 2 Hours/Week (Project)

Unit 1: Design considerations of Machine Elements (08 Hours) Basic procedure of Machine Design, Materials selection, Important mechanical properties of materials used in design, Codes and standards used in design, Preferred numbers, Manufacturing considerations in design. Concept of stress and strain (Linear, lateral, shear and volumetric), Hooke’s law, Poissons ratio, modulus of elasticity, modulus of rigidity, stress-strain diagrams for ductile and brittle materials, factor of safety, Theories of failure, Design for static loading. Review of types of loads and simple stresses. Stresses due to Biaxial loads.

Unit 2: Design for Fluctuating Loads (6 Hours) Types of variable stresses, Fluctuating stresses, Fatigue failure, fatigue strength and endurance limit, Introduction to S-N diagram, Low cycle and High cycle fatigue, Stress concentration factor and Notch sensitivity. Factors affecting fatigue strength. Goodman and Soderberg diagram, Modified Goodman’s diagrams for fatigue design. Cumulative fatigue damage.

Unit 3: Design of Shafts, Keys and Couplings (10 Hours) Design of solid and hollow shafts based on strength, rigidity, ASME code for shaft design. Keys, Types of keys, Design of keys and key ways. Couplings, Types of Couplings, Design of muff coupling, Design of rigid and flexible couplings.

Unit 4: Design of Springs (04 Hours) Types, Application and materials of springs, Stress and deflection equation for Helical springs, Styles of ends, Design of helical springs, Helical Springs in Parallel and Series, Design of Helical Springs for Variable Load.

Unit 5: Design of levers (04 Hours) Introduction to levers, Application of levers in engineering practice, Design of hand, foot and Crank Levers. Design of bell crank lever, design of rocker arm for exhaust valves

Unit 6: Design of Spur Gears (08 Hours) Introduction, Standard Proportions of Gear Systems, Gear Materials, various design considerations, Beam Strength of gear teeth- Lewis Equation, tangential loading, module Calculations, width calculations, Dynamic tooth loads, Spott’s Equation, types of gear tooth failures, Spur Gear construction, Design of Spur Gears.

List of Project areas: Students will perform projects of following designs for material selection, design calculations, assembly and detail drawing. 1. Design and drawing of Two/ Three stage Gear box used for any industrial applications 2. Design and drawing of shaft subjected under static and dynamic loads. 3. Design and drawing of rigid/ flexible flange coupling for any industrial application. 4. Design and drawing of levers used in industry



5. Design and drawing of helical spring for any industrial application Text Books:

1. V. B. Bhandari, Design of Machine Elements,

Tata McGraw Hill Publications,

2. R. K. Jain, Machine Design, Khanna Publication, 3. Pandya and Shah Machine Design, Charotar Publication, 4. Hall, Holowenko

Laughlin Machine Design, Tata McGraw Hill

Publication,

5. J.F. Shigley Design of Machine Element,

McGraw Hill Publication

6. M. F. Spotts Design of Machine Element,

Pearson Education Publication,

7. PSG Design data Book

Reference Books:

1. P. Kannaiah, Design of Machine Elements,

Scitech Publication,

2. H. Burr and Cheatam,

Mechanical Analysis and Design,

Prentice Hall Publication,

3. P. Kannaiah, Design of Transmission Systems,

Scitech Publication,

4. R. L. Norton Machine Design An Integrated Approach,

Pearson Education Publication

5. S. S. Wadhwa and S. S. Jolly

Machine Design A Basic Approach

Dhanapat Rai and Sons

Course Outcomes: Students will be able to: 1. Analyze the stress and strain mechanical components such as shaft, keys and couplings

and design the same for various industrial applications. 2. Design spur and helical gears for various applications. 3. Select different types of rolling contact bearings from manufacturer’s catalogue for

various industrial applications. 4. Analyze the stress and strain in power screw and design the same for various industrial

applications. 5. Analyze the stress and strain in threaded and welded joints and design the same for

various industrial applications. 6. Design mechanical components for fluctuating and reversible loading conditions.



FF No. : 654

IP228TLP THERMAL & FLUID ENERGY CONVERSION

Credits: 04 Teaching Scheme: Theory 3 Hrs / Week+ Lab 2 Hrs / Week Unit 1: Introduction & Fluid Properties (7 Hours) Definition of fluid, Newton’s law of viscosity, classification of fluid: Newtonian & Non-Newtonian fluids, ideal & real fluids, fluid properties: viscosity, compressibility, cohesion, adhesion, surface tension, capillarity, vapour pressure, Pascal’s law, continuity equation , types of flow , Bernoulli’s equation, applications of Bernoulli’s equation, orifice meter, venturimeter, pitot tube, mechanical gauges.

Unit 2: Fluid Machinery (5 Hours) Construction, working and applications of hydraulic turbines – Impulse- Pelton turbine, Reaction turbines- Francis and Kaplan turbine. Construction, working and applications of centrifugal pumps and reciprocating pumps.

Unit 3: Steam generators (7 Hours) Introduction, formation of a steam at a constant pressure, temperature Versus total heat graph during steam formation, steam properties, boiler performance, boiler efficiency, equivalent of evaporation and energy balance.

Unit 4: I.C. Engines (7 Hours) Classification of I.C. Engines, construction and working of two stroke, four stroke, S.I. and C.I. Engines, terms used in air cycles, thermodynamic air cycles- Otto, Diesel combustion cycles, cooling and lubrication systems of I.C. engines., applications of I.C. Engines.

Unit 5: Air Compressors (7 Hours) Introduction, classifications, working of single stage reciprocating air compressors, work done by a single stage reciprocating air compressors with and without clearance, multistage compression, two stage reciprocating air compressors with intercooler, Construction and working of centrifugal compressor and axial flow air compressors, Applications of compressed air.

Unit 6: Refrigeration and Air conditioning (7 Hours) Refrigeration: Air refrigeration working on Bell Coleman cycle, Simple vapour compression cycle, vapour absorption cycle, types and properties of refrigerants, p-h and T-s diagram, Air conditioning: window, split, central, and industrial air conditioning systems.

List of Practicals: 1. Verification of Bernoulli’s equation. 2. Study and demonstration of pumps and turbines. 3. Trial on petrol engine. 4. Trial on diesel engine. 5. Trial on reciprocating air compressor.



List of Project areas (Any 3 from below): Project -1: Fluid Mechanics Project -2: Fluid Machinery & steam generators Project -3: I C Engines Project -4: Air Compressors Project -5: Refrigeration and Air conditioning

Text Books:

1. Bansal R.K Fluid Mechanics and Hydraulic Machines

9th Laxmi Publication (P) Ltd.

2005

2. S.C. Gupta Fluid Mechanics and Hydraulic Machines

5th Pearson Education India,

2006

3. Jain A.K Fluid Mechanics and Hydraulic Machines

6th Tata Mac Graw Hill

1998

4. R K Rajput Thermal Engineering 8th Laxmi Publication (P) Ltd.

2010

5. P.K.Nag Engineering Thermodynamics

5th Tata McGraw-Hill Education

2005

Reference Books:

1. Modi P. N. and Seth S. M

Hydraulics and Fluid Mechanics

14th Standard Book House, New Delhi

2002

2. Khurmi R. S. and Gupta J. K

Thermal Engineering

15th S. Chand & Company Ltd,

2015

3. Kumar Vasantdani Thermal Engineering

4th Metropolitan Book Co., Delhi.

2006

4. P.L. Balleny Thermal Engineering

20th Khanna Publisher 2009

Course Outcomes: The student will be able to – 1. Understand basic concepts of fluids, classification of flows and measure fluid flow by various flow measuring devices. 2. Distinguish various types of hydraulic turbines, pumps 3. Analyze performance of boilers. 4. Understand basic concepts of thermodynamics and analyze air standard cycles. 5. Describe and analyze various types of air compressors. 6. Understand refrigeration and air conditioning principles



FF No. : 654

Credits: 02 Teaching Scheme: - Theory 2 Hrs/Week

Unit I (07 Hrs) Engineering Economic Analysis

Introduction, Concept of Money – Its Functions & worth. Inflation – Concept, Causes, Remedies to control inflation, Value of Currency, Factors governing exchange rates, Currency Fluctuations. Concept of Taxes, Types of Taxes – Direct & Indirect, Depreciation. Effect of above concepts on decision making. Significance of above concept in real life decision making

Unit II (07 Hrs) Time Value of Money & Life Cycle Costing

Concept of Interest, Time Value of Money – Basis for comparison of alternatives, Discount Rate, Compound Rate, Present Worth, Future Worth, Annual Worth, Annuity, Perpetuity. Life Cycle Costing - Introduction, methodology, applications of LCC in industrial world, differentiation with traditional costing methods, Capital Budgeting: DCF & NDCF Techniques: Payback, Discounted Payback, ARR, IRR, NPV, Annual Worth, Cost Benefit Ratio. Numerical Applications on Time Value of Money

Unit III (07 Hrs) Concept of Demand and Supply

Law of Demand & Supply: Meaning and Determinants of Demand. Demand Function. Law of Demand, Market Demand, Elasticity of demand. Types of elasticity. Measurement of elasticity. Significance and uses of the elasticity. Meaning and Determinants of Supply, Law of supply. Equilibrium of demand and supply i.e. price determination. Exceptions of Law of Demand & Supply.

Unit IV (07 Hrs) Concept of Utility, Competition Law of Diminishing Marginal Utility – Concept, Law of Diminishing Marginal Utility Price Determination, Competition – Concept, Types (Monopoly, Oligopoly, etc.), Benefits to Buyer & Seller, Economies of Scales, Law of Variable Proportions. Cases related with above concepts.

Text Books 1. Theusen H.G., Engineering Economic Analysis, Prentice Hall of India 2. Henry M. Steiner, Engineering Economic Principles, McGraw Hill 3. S.M. Mahajan, Engineering Economics, Everest Publishing House, Pune 4. Samuelson PA, Nordhaus WD, Economics, Tata McGraw Hill

HS201OPE:: ENGINEERING & MANAGERIAL ECONOMICS



Reference Books 1. Colin Drury, Management and Cost Accounting, English Language Book Society,

Chapman and Hall London. 2. Khan M. Y., Jain P. K., Financial Management, Tata McGraw Hill

Course Outcomes: Our students will be able to: 1. Analyze the effect of inflation, currency fluctuations, and taxes on decision making 2. Compare and select investment alternatives based on costs and time value of money 3. Analyze the impact of demand and supply on pricing of product and competition 4. Understand the concept of utility and competition and its relevance in business

environment



FF No. : 654

IP229LTH COMPUTER GRAPHICS


List of Practicals: 1) Introduction & use of basic AutoCAD commands to draw basic drawing entities –

Part 1 2) Introduction & use of basic AutoCAD commands to draw basic drawing entities –

Part 2 3) Introduction to modifying commands ( trim, extend, offset, array etc) 4) Simple 2D drafting (orthographic projections) 5) Complex 2D drafting – Part 1 (Assembly and details of any one of Machine

Components Cotter Joint, Knuckle Joint, Flange Joint, Rigid and Flexible Coupling, Stop Valve, Non Return Valve, Revolving Centers, Machine Vice, Tool Holder.)

6) Introduction to basic isometric commands. & Isometric drafting 7) Introduction to 3D commands (extrude, polyline, etc.) 8) Simple 3D drafting of simple mechanical components 9) One assembly and Complex 3D drawing for each student as a project

Text Books:

1. Ghosh, Machine Drawings with AutoCAD

Machine Drawings with AutoCAD

Revised Edition

Pearson Education

2008

2. N.D.Bhatt, V.M.Panchal

Machine Drawing.

49th edition Charotar Publishing House Private Limited

2014

Reference Books:

1. K.L.Narayana, P. Kannaiah, K. Venkatata Reddy

Machine drawing 4th Edition New Age International Pvt Ltd Publishers

2009

2. Farazdak Haideri Machine Drawing and Computer Graphics

2nd Edition Nirali Publication

2009

Course Outcomes:- The student will be able to – 1. Analyze and draw the 2D and 3D views using AutoCAD 2. Prepare part and assembly drawing along with Bill of Material using AutoCAD 3. Communicate and present ideas through drawing using AutoCAD



FF No. : 654

IP230PRJ :: MINI PROJECT

Credits: 02 Teaching Scheme: - Laboratory 2 Hrs/Week

Prerequisites: Nil

Guidelines 1. Mini Project can be an individual or a group activity depending on the depth and

scope of the topic. 2. The project work can be any of the form given below (but not restricted to below

mentioned topics only) : a) Making physical working models, prototypes, scaled models, of a concept

machine. b) Making virtual / CAD models of machines / concepts. c) Making study, modeling, analysis, programming and simulation of a system /

machine operation / process. d) Making study / teaching modules of a sufficiently complex topic for pedagogy

purposes. 3. A complete assembly and details drawings of the project should be submitted along

with a detailed project report, where applicable. 4. A Detailed background / field / literature survey, related to the topic must be made

presented in the report. 5. Entire work should be presented at the end of the Semester.

Course Outcomes : Students will be able to 1. Survey literature for problem identification. 2. Apply basic engineering fundamentals in the domain of practical applications to

analyze a concept/system/machine operation/process etc. 3. Cultivate the habit of working in a team and attempt a problem solution in a right

approach 4. make physical working model/charts/prototype/scaled model/ CAD model etc, carry

out a survey/ conduct experimentation 5. prepare project report and present at the end of semester

Documents

Bansilal Ramnath Agarwal Charitable Trust’s … cutting tools, speed, feed and depth of cut, Machining time calculations, Geometry of single point cutting tools, tool signature