Yes/No Theory/ Practical B.TECH

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DAYALBAGH EDUCATIONAL INSTITUTE FACULTY OF ENGINEERING

B.TECH. (CIVIL, ELECTRICAL, FOOTWEAR & MECHANICAL): 2017-18

Course Code Course Title Credits End Sem.

Yes/No

Theory/

Practical B.TECH. (CIVIL) SIXTH SEMESTER

CEM601 DESIGN OF STEEL ELEMENTS 3.0 Y T

CEM602 IRRIGATION ENGINEERING 3.0 Y T

CEM603 DSGN OF REINFORCED CONCRETE STRUC.I 3.0 Y T

CEM604 STRUCTURAL ANALYSIS II 3.0 Y T

CEM605 FOUNDATION ENGINEERING 3.0 Y T

CEM607 GEOMATICS II 3.0 Y T

CEM608 GEOMATICS LAB 1.0 Y P

EGC681 DESIGN ENGG./ THEME DEVELOP. PROJECT 1.5 Y P

RDC681 VILLAGE INDUSTRIES & ENTERPRENUERSHIP 2.0 Y T

CEC681 CULTURAL EDUCATION 2.0 N T

CAC681 CO-CURRICULAR ACTIVITIES 3.0 N T

Mainstream Civil

CEM611 COMPUTER AIDED DSGN. IN CIVIL ENGG. 3.0 Y T

CEM612 CAD LAB 1.5 Y P

Architectural Technology Specialisation

CEM613 DISASTER MITIGATION & PLANNING 3.0 Y T

CEM614 PRINCIPLES OF TOWN PLAN.& ARCH. LAB 1.5 Y P

Computer Science Specialisation

EEM611 DESIGN & ANALYSIS OF ALGORITHMS 3.0 Y T

EEM612 COMPUTER SCIENCE LAB 1.5 Y P

B.TECH. (ELECTRICAL) SIXTH SEMESTER

ASM601 ELECTRICAL ENGINEERING MATERIALS 3.0 Y T

EEM601 MICRO PROCESSORS & MICROCONTROLLERS 3.0 Y T

EEM602 MICRO PROCESSORS LAB. 1.5 Y P

EEM603 POWER SYSTEMS I 3.0 Y T

EEM604 APPLIED SYSTEMS ENGINEERING 3.0 Y T

EEM609 STREAM SEMINAR 1.0 Y P

MAM681 ADVANCED OPTIMIZATION TECHNIQUES 3.0 Y T

Mainstream Electrical

EEM605 POWER ELECTRONICS 3.0 Y T

EEM606 POWER ELECTRONICS LAB 1.5 Y P

Electronics Specialisation

EEM605 POWER ELECTRONICS 3.0 Y T

EEM606 POWER ELECTRONICS LAB 1.5 Y P

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B.TECH. (FOOTWEAR TECHNOLOGY) SIXTH SEMESTER

FEM601 FOOTWEAR PATT. DSGN. & GRAD. SYS. 3.0 Y T

FEM602 FOOTWEAR PATT.DSGN. & GRAD.SYS. LAB 1.0 Y P

FEM603 LEATHER GOODS& GARMENTS MANUF.TECH. 3.0 Y T

FEM604 LEATHER GOODS& GARM. MANU.TECH. LAB 1.0 Y P

FEM605 FINISHING & PACKING TECHNOLOGY 3.0 Y T

FEM606 FINISHING & PACKING TECHNOLOGY LAB 1.0 Y P

FEM608 STREAM SEMINAR 1.0 N P

EEM608 CONTROL ENGINEERING 2.0 Y T

MEM611 STATISTICAL QUALITY CONTROL 3.0 Y T

MEM612 STATISTICAL QUALITY CONTROL LAB 1.0 Y P

EGC681 DESIGN ENGG. /THEME DEVELOP. PROJECT 1.5 Y P

RDC681 VILLAGE INDUSTRIES & ENTREPRENEURSHIP 2.0 Y T

Mainstream Footwear Technology

FEM610 OPERATIONS IN FOOTWEAR MANUFACTURE-I 3.0 Y T

FEM611 OPERATIONS IN FOOTWEAR MANUFACTURE-I LAB 1.0 Y P

Quality Control and Management specialization

FEM612 TECH. OF LEATHER GOODS MANUFACT. 3.0 Y T

FEM613 TECH. OF LEATHER GOODS MANU. LAB 1.0 Y P

Computer Aided Shoe Designing Specialization

FEM614 DESIGN & ANALYSIS OF ALGORITHMS 3.0 Y T

FEM615 COMPUTER SCIENCE LAB 1.0 Y P

B.TECH. (MECHANICAL) SIXTH SEMESTER

MEM601 MECHANICAL ENGINEERING DESIGN I 4.0 Y T

MEM602 MECHANICAL ENGG. DESIGN PRATICE I 2.0 Y P

MEM603 METAL CUTTING & TOOL DESIGN 3.0 Y T

MEM604 PRODUCTION ENGINEERING LAB. 1.0 Y P

MEM605 HEAT TRANSFER 3.0 Y T

MEM606 HEAT TRANSFER LAB. 1.0 Y P

EEM608 CONTROL ENGINEERING 2.0 Y T

MEM609 STREAM SEMINAR 1.0 N P

MAM681 ADVANCED OPTIMIZATION TECHNIQUES 3.0 Y T

Mainstream Mechanical

MEM607 AUTOMOBILE ENGINEERING 3.0 Y T

MEM608 AUTOMOBILE ENGINEERING LAB 1.5 Y P

Industrial Engineering Specialisation

MEM611 STATISTICAL QUALITY CONTROL 3.0 Y T

MEM612 STATISTICAL QUALITY CONTROL LAB 1.5 Y P

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Course Number: ASM601, Course Title: ELECTRICAL ENGINEERING MATERIALS Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2007-08 Total Credits:3, Periods(55 mts. Each)/week: 5(L:4+T:1+P:0+S:0), Min.pds./sem.: 65 UNIT 1: CRYSTALLINE NATURE OF SOLIDS

Atomic bonding. Bonding in materials. Properties dependent on bonding. Introduction to crystallography. Geometry of perfect crystals (cubic system). Designation of planes and directions.

Bragg’s law.

Imperfection in crystals. Point defects. Line defects. Surface defects. Bulk defects (brief idea).

UNIT 2: ALLOY FORMATION

Solid solutions. Interstitial and sustitutional intermetallic compounds. Hume Rothery rules for the formation of ideal solid solutions. Simple phase diagrams. Fe-Fe3C-equilibrium diagram. Non equilibrium cooling Heat treatment of steels.

UNIT 3: ELECTRICAL CONDUCTION IN MATERIALS

Simple classical model. Band model of conductivity. Electrical resistivity of conductors. Resistor materials.

SUPER CONDUCTIVITY: Introduction. Critical field and critical current density. Properties of super conductors. Applications.

SEMICONDUCTING MATERIALS: Elemental semiconductors. III-V compounds. Organic semiconductors. Elementary idea of purification and doping techniques of semiconductors.

UNIT 4: DIELECTRICS

Introduction. Polarization. Internal field in solids and liquids. Frequency dependence of relative permeability and mobility. Dielectric loss. Ferroelectricity. Piezo-electricity. Uses of dielectrics.

UNIT 5: MAGNETIC PROPERTIES

Dia, para and ferromagnetism. Wies field and magnetic domains. Antiferromagnetism and ferri- magnetism. Ferro-magnetic anisotropy and magnetostriction.

OPTICAL PROPERTIES OF MATERIALS: Introduction. Refraction. Absorption in dielectrics Luminescence. Lasers.

SUGGESTED READINGS:

Raghavan V: INTRODUCTION TO MATERIALS SCIENCE Van Vlack: ELEMENTS OF MATERIAL SCIENCE

Azoroff & Brophy: ELECTRONIC PROCESSES IN MATERIALS Pease, Rose & Wulf: ELECTRONIC PROPERTIES

Dekker: ELECTRICAL ENGINEERING MATERIALS

Course Number: CEM601, Course Title: DESIGN OF STEEL ELEMENTS

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2015-16 Total Credits:3, Periods(55 mts. Each)/week: 4(L:3+T:1+P:0+S:0), Min.pds./sem.: 39 UNIT 1: INTRODUCTION

Properties of steel – Structural steel sections – Limit State Design Concepts – Loads on Structures – Connections using rivets, welding, bolting – Design approach, elastic method, limit state design- Design of bolted and welded joints – Eccentric connections - Efficiency of joints.

UNIT 2

Tension members, steel members subject to axial tension. Compression members, struts and columns. Roof trusses, roof & side coverings, design loads, purlins, members, end bearings.

UNIT 3

Types of compression members – Theory of columns – Basis of current codal provision for

compression member design – Slenderness ratio – Design of single section and compound section compression members – Design of laced and battened type columns – Design of column bases – Gusseted base.

UNIT 4

Design of laterally supported and unsupported beams – Built up beams – Beams subjected to uniaxial and biaxial bending

UNIT 5

Design of plate girders - Intermediate and bearing stiffeners – Flange and web splices. Beam column, stability consideration, interaction formulae, column bases, slab base, gusseted base and grillage footings.

SUGGESTDED READINGS:

Arya, A.S. and Ajmani, J.L., “Design of Steel Structures”, Nem Chand & Bros.

Duggal, S.K., “Design of Steel Structures”, Tata McGraw-Hill.

Negi, L.S., “Design of Steel Structures”, Tata McGraw-Hill.

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Course Number: CEM602, Course Title: IRRIGATION ENGINEERING

Importance of Irrigation Engineering, purposes of Irrigation, objectives of Irrigation, Benefits of Irrigation, Advantages of various techniques of irrigation- Furrow Irrigation, Boarder strip Irrigation, Basin Irrigation, Sprinkler Irrigation , Drip Irrigation.

METHODS OF IRRIGATION: Advantages and disadvantages of irrigation, water requirements of crops, factors affecting water requirement, consumptive use of water, water depth or delta , Duty of water, Base Period, relation between delta, duty and base period, Soil crop relation-ship and soil fertility.

UNIT 2: CANAL IRRIGATION

Classifications of canals, canal alignment, Inundation canals, Bandhara irrigation, advantages and disadvantages, Silt theories-Kennedy's theory, Lacey's theory, Drawbacks in Kennedy's &Lacey's theories, comparison of Lacey's and Kennedy's theories, Design of unlined canals based on Kennedy &Lacey's theories.

LINED CANALS: Types of lining, selection of type of lining, Economics of lining, maintenance of lined canals, silt removal, strengthening of channel banks, measurement of discharge in channels, design of lined canals, methods of providing drainage behind lining.

LOSSES IN CANALS, WATER LOGGING AND DRAINAGE: Losses in canalsEvaporation and seepage, water logging, causes and ill effects of water logging anti wter logging measures. Drainage of land, classification of drains - surface and subsurface drains, Design considerations for surface drains, Advantages and maintenance of tile drains.

UNIT 3: INVESTIGATION AND PREPARATION OF IRRIGATION PROJECTS

Classification of project, Project preparation-investigations, Design of works and drawings, concept of multi - purpose projects, Major, Medium and miner projects, planing of an irrigation project, Economics & financing of irrigation works. Documentation of project report.

UNIT 4: TUBE - WELL IRRIGATION

Types of tube wells - strainer type, cavity type and slotted type. Type of strainers, Aquifer, porosity, uniformity coefficient, specific yield & specific retention, coefficients of permeability,transmissibility and storage. Yield or discharge of a tube well , Assumptions , Theim 's

&Dupu it ’s formulae, Lim it ations of Theim 's and Dupuit's formulae. Interference of tube wells with canal or adjoining tube-wells, causes of failure of tubewells, optimum capacity, Duty and delta of a tube well. Rehabilitation of tubewell.

UNIT 5: RIVER TRAINING WORKS

Objectives, classification of river-training works, Design of Guide Banks. Groynes or spurs - Their design and classification ISI. Recommendations of Approach embankments and afflux embankments, pitched Islands, Natural cut-offs and Artificial cut-offs and design Considerations.

SUGGESTED READINGS:

S.K.Sharma, Principles & practice of Irrigation Engg.; S. Chand, Limited.

B.C. Punmia, PandeB.B.Lal, Irrigation & Water Power Engg.; Laxmi Publications (p) Ltd Dr. Bharat Singh Fundamentals of Irrigation Engg.; Nem Chand & Bros

S.R.Sahasrabudhe, Irrigation Engg.& Hydraulic Structure; S. K. Kataria& Sons

Varshney, Gupta & Gupta, Irrigation Engg.& Hydraulic Structure; Nem Chand and Brothers Santosh Kumar Garg, Irrigation Engg.& Hydraulic Structure; Khanna Publishers

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Course NUMBER: CEM603, Course Title: DESIGN OF REINFORCED CONCRETE STRUCTURES-I Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2014-15

Total Credits:3, Periods(55 mts. each)/week:3(L:3+T:1+P:0+S:0), Min.pds./sem:40 UNIT 1 & 2

Basic Concepts of Reinforced Concrete Design : Working stress and limit state design methods.

Design of R.C. Beams in Flexure : Singly and doubly reinforced rectangular/flanged sections, design for shear, bond and anchorage of reinforcement, limit states of deflection and cracking.

UNIT 3

Design for Torsion : Design of RC beams subjected to torsion.

One-way and two-way slabs, design of staircases.

UNIT 4

Design of compression members for axial loads and axial load plus uniaxial moment.

Foundation types, design of isolated footings, introduction to combined footings.

UNIT 5

Stability analysis of retaining walls, design of gravity, cantilever type retaining walls SUGGESTED READINGS:

1. Shah, V.L. et.al., “Limit State Theory and Design of Reinforced Concrete”, Structures Publications. , 2007 2. Pillai, S.U. and Menon, D., “Reinforced Concrete Design”, Tata McGraw- Hill. 2003

3. Varghese, P.C., “Limit State Design of Reinforced Concrete”, Prentice-Hall. 2002 4. Park, R. and Pauley, T., “Reinforced Concrete Structures”, John Wiley. 1976

5. Gambhir, M.L., “Fundamentals of Reinforced Concrete Design”, Prentice-Hall of India. 2006

Course Number: CEM604, Course Title: STRUCTURAL ANALYSIS II

Stiffness, flexibility, flexibility and stiffness matrices

Influence Lines: Analysis for different types of moving loads, use of influence line diagrams, application to determinate structures.

UNIT 2: REDUNDANT STRUCTURES

Muller-Breslau principle with application to determinate and redundant structures. Qualitative ILD for continuous beams, frames and arches.

UNIT 3: DISPLACEMENT APPROACH

basic principles. Slope deflection method. Moment distribution method, frame with/without sway, use of symmetry and anti-symmetry , Matrix displacement method, basic principles, application to beams, trusses and frames.

UNIT 4: THEORY OF PLATES AND SHELLS

Analysis of plates, folded plates and singly curved shells: conventional and approximate methods.

UNIT 5: SPACE AND CABLE STRUCTURES

Analysis of Space trusses using method of tension coefficients – Beams curved in plan Suspension cables – suspension bridges with two and three hinged stiffening girders.

SUGGESTED READINGS:

Wang, C.K., “Intermediate Structural Analysis”, McGraw Hill.

Norris, C.H. et.al., “Elementary Structural Analysis”, Tata McGraw Hill.

James, M. Gere, “Mechanics of Materials”, 5th Ed., Nelson Thornes.

Reddy, C.S., “Basic Structural Analysis”, Tata McGraw Hill.

Weaver, W. Jr. and Gere, J.M., “Matrix Analysis of Framed Structures”, CBS Publishers.

Punmia.B.C., Ashok Kumar Jain and Arun Kumar Jain, “Theory of Structures”, Laxmi Publications, 2004

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Course Number: CEM605, Course Title: FOUNDATION ENGINEERING

Role of civil engineer in the selection, design and construction of foundation of civil engineering structures, brief review of soil mechanics principles used in foundation engineering.

UNIT 2: SOIL EXPLORATION

Methods of soil exploration; boring, sampling, penetration tests, correlations between penetration resistance and soil design parameters.

UNIT 3: EARTH PRESSURE AND RETAINING WALLS

Earth pressure at rest, active and passive earth pressure, Rankine and Coulomb’s earth pressure theories, earth pressure due to surcharge, retaining walls, stability analysis of retaining walls, proportioning and design of retaining walls.

UNIT 4: FOUNDATIONS

Types of foundations, mechanism of load transfer in shallow and deep foundations, shallow foundations, Terzaghi’s bearing capacity theory, computation of bearing capacity in soils, effect of various factors, use of field test data in design of shallow foundations, stresses below the foundations, settlement of footings and rafts, proportioning of footings and rafts, sheeting and bracing of foundation excavation.

PILE FOUNDATION: Types and methods of construction, estimation of pile capacity, capacity and settlement of group of piles, proportioning of piles. Well foundations: Methods of construction, tilt and shift, remedial measures, bearing capacity, settlement and lateral stability of well foundation.

UNIT 5: SLOPES

Mode of failure – mechanism, stability analysis of infinite slopes, methods of slices, Bishop’s simplified method. Machine Foundations: Types of machine foundations, mathematical models, response of foundation – soil system to machine excitation, cyclic plate load test, block resonance test, criteria for design.

SUGGESTED READINGS:

Ranjan, G. and Rao, A.S.R., “Basic and Applied Soil Mechanics”, New Age.

Das, B.M., “Principles of Foundation Engineering”, PWS.

Som, N.N. and Das, S.C., “Theory and Practice of Foundation Design”, Prentice-Hall.

Couduto, Donald P., “Geotechnical Engineering – Principles and Practices”, Prentice-Hall.

Peck, R.B., Hanson, W.E. and Thornburn, T.H., “Foundation Engineering”, John Wiley.

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Course Number: CEM607, Course Title: GEOMATICS II

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2015-16 Total Credits:3, Periods(55 mts. Each)/week: 4(L:3+T:1+P:0+S:0), Min.pds./sem.: 52 UNIT 1: PHOTOGRAMMETRY

Photogrammetric terms; type of photographs; mosaics and photomaps; Perspective geometry of near vertical and tilted photographs, heights and tilt distortions; Rectification and orthophotographs; Flight planning; Stereoscopy base lining, parallax equation and stereo measurements for height determination.

UNIT 2: REMOTE SENSING

Introduction to remote sensing, remote sensing system and components; Physics of remote sensing including wave equation and EMR propagation through medium, EMR source characteristics, Role of atmosphere, Physics of EMR interaction with objects, interaction with soil, vegetation, water, snow, rocks, etc.

Sensor characteristics: various resolutions: spectral, spatial, temporal, multi-concept in remote sensing, FOV, IFOV, characteristics of various remote sensing satellites and sensors.

UNIT 3: DIGITAL IMAGE PROCESSING

Concept of digital image; Image processing; interpretation elements, manual versus digital interpretation, Geometric and radiometric distortions in images and their removal, image histogram and histogram manipulation, image convolution, high and low pass filters, directional and non- directional image derivatives; Image classification, unsupervised and supervised-various methods, training data selection, classification accuracy measures-error matrix.

UNIT 4: GEOGRAPHICAL INFORMATION SYSTEM (GIS)

Introduction: Geoinformation and its significance, definition of GIS, overview of application fields, history of GIS.

GIS DATA: Spatial and non-spatial data, spatial data model and significance- raster, tessellation, vector, 2.5D model, spatio-temporal models, hybrid, object oriented; advantages and disadvantages of various models; Topology and topological models; Spatial referencing using coordinates and geographic identifiers, metadata.

UNIT 5: SPATIAL DATA ACQUISITION

Land Surveying, GPS, photogrammetry, LiDAR, GPR, Remote Sensing; Attribute data sources;

Spatial data input techniques- digitizing, scanning, georeferencing; Attribute data input; Data storage, RDBMS, database operations.

Spatial data editing functions: Raster-vector conversion, coordinate and projection transformation, data merging methods, data compression; Quality of spatial data, Non-spatial data editing functions.

GIS analysis functions: Retrieval, classification, measurement, neighborhood, topographic, interpolation, overlay, buffering, spatial join and query, connectivity, network functions, watershed analysis, viewshed analysis, spatial pattern analysis, spatial autocorrelation, trend surface analysis.

Applications in Civil Engineering SUGGESTED READINGS:

Wolf, P, DeWitt, B., and Wilkinson, B., Elements of Photogrammetry with Application in GIS, McGraw-Hill, 2014.

Rampal, K. K., 1982, Textbook of Photogrammetry, Oxford & IBH Publishing Co.

Lillesand, T, M., Kiefer, R, W. and Chipman, J. W., Remote Sensing and Image Interpretation, 5^th ed, John Wiley and Sons, 2004.

Rees, W. G., Physical principle of remote sensing, 2^nd Edition, Cambridge University Press, 2001.

Schowengerdt, R. A., Remote Sensing: Models and methods for image processing, 3^rd ed, Academia Press, 2007.

Jensen, J. R., Introductory digital image processing, 3^rd ed, Prentice Hall, 2005.

Campbell, J. B., Introduction to remote sensing, 5^thed, Guilford Press, 2011.

Lo, C. P., and Yeung, A.K W., Concepts and techniques of GIS, Prentice Hall of India, 2002

Burrough, P. A., and McDonnell, R. A., Principles of Geographical Information Systems, 2^nd ed, Oxford University Press, 1998.

Bossler, John D., Campbell, James B., McMaster, Robert B. and Rizos, Chris, Manual of Geospatial Science and Technology, 2^nd ed, CRC press, 2010.

Demers, M. N., Fundamentals of Geographic Information Systems, John Wiley, 3^rd ed, 2002

Longley, P. A., Goodchild, M. F., Maguire, D. J., and Rhind, D. W., Geographic Information Systems and Science, 2^nded, John Wiley, 2005.

Agarwal, C.S. and Garg, P.K., “Remote Sensing in Natural Resources Monitoring and Management”, Wheeler Publishing House.

Bossler, J.D., “Manual of Geospatial Science and Technology”, Taylor and Francis.

Burrough, P.A. and McDonnell, R.A., “Principles of Geographic Information System”, Oxford University Press.

Chandra, A.M. and Ghosh, S.K., “Remote Sensing and Geographical Information Systems”, Alpha Science.

Gopi, S., “Global Positioning System: Principles and Applications”, Tata McGraw Hill.

Course Number: CEM608, Course Title: GEOMATICS LAB.

Class: B.Tech., Status of Course: CORE COURSE, Approved since session: 2015-16 Total Credits:1, Periods(55 mts. Each)/week: (L:0+T:0+P:0+S:0), Min.pds./sem.:

Based on the above subject

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Course No: CEM611, Course Title: COMPUTER AIDED DESIGN IN CIVIL ENGINEERING Class: B.Tech, Status of Course: Major Course, Approved since session: 2014-2015

Total Credits:3, Periods(55 mts. each)/week:3(L:3+T:1+P:0+S:0), Min.pds./sem:39 UNIT 1: GENERAL CONCEPTS & MATHEMATICS PRELIMINARIES

Introduction to Computer Aided Design, Brief history and over view of finite element method, matrices and matrix operation method of solution of simultaneous equations. Shape functions &

their derivation. Introduction to boundary value problems and variation calculus.

UNIT 2: DIRECT STIFFNESS METHOD

Introduction to direct stiffness method and its application to springs, electrical networks, flow in pipes and bars. Truss analysis with direct approach. Determination of local element characteristics, assemblage of global element characteristics, application of the prescribed displacements and loads

& solution.

UNIT 3: VARIATIONAL FORMULATION

Variational approach to Boundary value problems. The weak formulation. The Euler-Lagrange equation. One dimensional axial deformation and heat conduction problems. Geometric and natural boundary conditions.

UNIT 4: INTRODUCTION TO WEIGHTED RESIDUAL METHODS

Galerkin’s approach to one dimensional problems. Completeness requirements, isoparametric elements and concepts of numerical integration.

UNIT 5: APPLICATION TO SOLID MECHANICS

Introduction to theory of elasticity, principle of virtual displacements, plane stress and plane strain problems, Axi-Symmetric and three dimensional stress analysis.

SUGGESTED READINGS:

1. FRANK L. STASA – APPLIED FINITE ELEMENT ANALYSIS FOR ENGINEERS 2. PAUL ALLAIRE – INTRODUCTION TO FINITE ELEMENT METHOD

3. ZINKIEWICZ, O.C – THE FINITE ELEMENT METHOD

4. HUEBNER, K.H. – THE FINITE ELEMENT METHOD FOR ENGINEERS 5. WILLIAM B. BICKFORD – FINITE ELEMENT METHOD

6. DESAI & ABEL – INTRODUCTION TO THE FINITE ELEMENT METHOD

Course No: CEM612, Course Title: COMPUTER AIDED DESIGN IN CIVIL ENGINEERING LAB Class: B.Tech, Status of Course: Major Course, Approved since session: 2014-2015

Total Credits:1.5, Periods(55 mts. each)/week:3(L:0+P:2+S:0), Min.pds./sem:39 LIST OF EXPERIMENTS:

Simulation will be performed on STAAD PRO on real life problems.

SUGGESTED READINGS:

1. Krishnamurthy, D., “Structural Design & Drawing – Vol. II and III, CBS Publishers, 2010.

2. Shah V L and Veena Gore, “Limit State Design of Steel Structures” IS800-2007, Structures Publications, 2009 3. STAAD PRO User Manual

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Course Number: CEM613, Course Title: DISASTER MITIGATION & PLANNING Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2015-16 Total Credits:3, Periods(55 mts. Each)/week: 4(L:3+T:1+P:0+S:0), Min.pds./sem.: 52 UNIT 1: CONCEPT OF DISASTER MANAGEMENT AND MITIGATION

Types of Disasters-causes and impact-hazard and vulnerability assessment-tools and techniques- Pre-disaster mitigation safety management system- Strategies for implementation-Community based Disaster management-Remote sensing and GIS application-Post disaster recovery and rehabilitation

UNIT 2: EARTHQUAKE RESISTANT DESIGN

Introduction to Earthquake-Seismic zones-Major earth quake Case studies-Causes and consequences of Earthquake-Design of Buildings for Earth quake resistance-Structural systems- Seismic design code provision-Design of non-structural elements.

UNIT 3: FLOOD RESISTANT DESIGN

Introduction, Causes and consequences of Flood- Case studies Major Flood prone areas-Flood resistant Designs -Structural systems.

UNIT 4: FIRE RESISTANT DESIGN

Introduction, Causes and consequences of Fire- Case studies of Major Fire prone areas-Fire resistant Designs -Structural systems.

UNIT 5: LANDSLIDE

Introduction, Causes and consequences of Landslides- Case studies of Major Landslide prone areas -Fire resistant Designs -Structural systems.

SUGGESTED READINGS:

DISASTER MANAGEMENT, Global challenges and local solutions, DISASTER MANAGEMENT by GK GHOSH, Training Module on Urban risk mitigation Chandrani Bandhopadhyay, DISASTER EDUCATION AND MANAGEMENT Rajendra Kumar Bhandari, DISASTER SCIENCE AND MANAGEMENT by Tushar Bhattacharya, EARTH AND ATMOSPHERIC DISASTER MANAGEMENT:

Nature and Man-made

Course Number: CEM614, Course Title: PRIN. OF TOWN PLANNING & ARCHITECTURE LAB Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2015-16 Total Credits:1.5, Periods(55 mts. Each)/week: 3(L:0+T:0+P:3+S:0), Min.pds./sem.: 39

The students are given onsite training and they are exposed to the principles of Dayalbagh town planning and architecture of Dayalbagh which is similar to Danish architecture. Some practical assignments will be given for them to plan a town that is eco-friendly and equipped with sustainable models of energy.

Course Number: EEM601, Course Title: MICROPROCESSORS & MICROCONTROLLERS Class: B.Tech., Status of Course: MAJOR, Approved since session 2015-16

Total Credits:3, Total pds. (55 mts each)/week: 4(L:3+T:1+P:0+S:0)Min. pds./sem.: 52

UNIT 1: INTRODUCTION [11]

Concept of Bus Organised Computers, SAP-1 and Architecture of 8085, Functional Block Diagram, Pin Diagram, Machine Cycles and Timing Diagram Memory interfacing.

UNIT 2: ASSEMBLY LANGUAGE PROGRAMMING [10]

Addressing Modes, Instruction Set, Development of Assembly Language Programs.

UNIT 3: INTERRUPTS AND INTERFACING [10]

Interrupts in 8085. Types of Interrupts, Interrupt Servicing, Multiple Interrupt Requests and their Handling, Programmable Interrupt Controller 8259A.

I/O Interfacing- Memory Mapped I/O and I/O Mapped I/O. 8255 Programmable Peripheral Interface.

UNIT 4: DMA AND USART [11]

Direct Memory Access, Need for DMA and 8257 DMA Controller.

Serial Data Transfer, USART8251.

UNIT 5: MICROCONTROLLERS [10]

Architecture of 8051, Memory Organisation, Addressing Modes, Instruction Set, Simple Programs.

8051 Interput Structures, Timer and Serial Functions, Parallel Port Features, Power Control Features.

SUGGESTED READINGS:

Gaonkar R.S.: “Microprocessor Architecture Programming and Applications with 8085”, 3^rd Edition Penram International Publishing House.

Kenneth L. Short: - “Microprocessors and Programmed Logic.” second edition, PHI.

Kanneth J.Ayala: - “The 8051Microcontroller Architecture, Programming and Applications, "Second Edition, Thomson.

Malvino & Brown: -“Digital Computer Electronics.” 3^rd Edition, TMH.

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Course Number: EEM602, Course Title: MICROPROCESSORS LABORATORY Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session 2015-16

Total Credits:1.5, Total pds. (55 mts each)/week: 3(L:0+T:0+P:3+S:0)Min. pds./sem.: 39 1. Assembly language program for adding/subtracting/multiplying two numbers.

2. 8085 programs for block move, sorting a block in ascending order/descending order.

3. 8085 assembly language program based on loops.

4. 8085 programs involving PPI 8255 chip 5. 8085 programs involving ADC/DAC chips.

Course Number: EEM603, Course Title: POWER SYSTEMS-I

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2015-16 Total Credits:3, Periods(55 mts. each)/week: 4(L:3+T:1+P:0+S:0), Min.pds./sem: 52 UNIT 1: POER GENERATION AND SUPPLY SYSTEMS

Generation of Power: Thermal, Nuclear, Hydro and renewable source power generation.

Distribution System: Types of distribution systems. Section and size of feeders. Voltage drops in distributors. Economics of power system operation. Cost of electrical energy and electricity tariff.

UNIT 2: OVERHEAD TRANSMISSION LINES

Types of conductors. Calculation of inductance and capacitance of single phase, double circuit transmission lines, three phase lines with stranded and bundled conductors. Generalized ABCD constants, Equivalent circuits of short, medium and long lines. Ferranti Effect. Line Performance:

Regulation and efficiency of short, medium and long lines. Series and shunt compensation.

UNIT 3: MECHANICAL DESIGN OF OVERHEAD LINES

Calculation of Sag: Different types of towers, sag-tension calculations, sag template, stringing chart, economical design of conductors, effect of ice loading and wind pressure, Vibrations and corona losses. Line Insulators: Types, material, defects and testing. String efficiency, voltage distribution in string of suspended insulators, Capacitance grading.

UNIT 4: CABLES

Use of cables and its advantages and disadvantages. Calculation of capacity of cables, charging current, stress grading, power factor and heating of cables, capacitance of cables, cable laying, construction and characteristics of HV and EHV cables, Over voltages and insulation coordination.

Methods of Fault location in cables.

UNTI 5: POWER ANGLE DIAGRAM AND STABILITY

Maximum steady state power. Power angle diagram. Problems of system stability, Steady state stability and methods to improve the same. Swing Equation. Equal Area criterion, Step by step method for solution of swing equation. Introduction to transient and dynamic stability. Methods of simulation for transient stability.

SUGGESTED READINGS:

IJ Nagrath & DP Kothari: POWER SYSTEMS ENGINEERING

AJ Wood & BF Wollenberg: POWER GENERATION, OPERATION AND CONTROL Soni, Gupta & Bhatnagar: A COURSE IN ELECTRICAL POWER

T Gonen: ELECTRIC POWER TRANSMISSION SYSTEM ENGINEERING P Kunder: POWER SYSTEM STABILITY AND CONTROL

Glover and Sharma: POWER SYSTEM ANALYSIS AND DESIGN

PM Andersong and AA Foud: POWER SYSTEM CONTROL AND STABILITY

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Course Number: EEM604, Course Title: APPLIED SYSTEMS ENGINEERING Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session 1996-97 Total Credits:3, Total pds.(55 mts each)/week: 4(L:3+T:1+P:0+S:0)Min. pds./sem.: 52 UNIT 1: INTRODUCTION TO SYSTEMS THEORY

Need for systems approach. The nature of general systems, laws and theories. Definition of a system. Through and across variable. Objectives of system analysis. Analysis techniques and operational concepts of system analysis.

UNIT 2: SYSTEM, COMPONENTS AND INTERCONNECTION

Measurements and terminal representation of simple components. Fundamental axiom of physical system theory. Component model postulate. System graph. Cutset and circuit postulates. Modeling of linear time invariant continuous time systems(s-domain models).

UNIT 3: FORMULATION TECHNIQUES

Branch, chord and branch-chord formulation. Their relative merits. Solution of s-domain equations.

Step function response and sinusoidal response. Multiterminal representations. Tree transformations. Derivation of equations of a system through sub-system to system approach.

UNIT 4: STATE EQUATION FORMULATION

Order of complexity. Formulation of state equations for nondegenerative and degenerative systems.

Some simple examples to illustrate the techniques of derivation of the state equation of time varying and non-linear systems. Response evaluation using state transition matrix. Discretisation of continuous time systems. Simple example to illustrate the solution of non-linear state equations using numerical methods like Euler's method, Adams-Bashforth and Adams-Moulton methods.

UNIT 5: STABILITY AND RELIABILITY

Performance characteristics of linear time invariant systems. Concept of stability in the same of Liapunov. Stability from the location of eigen values. Sensitivity. controllability. System reliability.

Reliability function. System failure rate. System meantime before failure. Topological reliability.

Reliability of simple structures.

SUGGESTED READINGS:

Koeing HE & Blackwell WA: ELECTROMECHANICAL SYSTEM THEORY Mohalanarbis AK: INTRODUCTION TO SYSTEM ENGINEERING

Koeing HE, Tokad Y & Kesavan HK: ANALYSIS OF DESCRETE PHYSICAL SYSTEMS Rose PH: NETWORKS AND SYSTEMS

urse Number: EEM605, Course Title: POWER ELECTRONICS

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session 2015-16 Total Credits:3, Total pds. (55 mts each)/week: 3(L:3+T:0+P:0+S:0)Min. pds./sem.: 39 UNIT 1: POWER DEVICES AND SINGLE PHASE RECTIFIER CIRCUITS

Power diodes. SCRs, triac, diac, Mosfets, IGBTS. Rating characteristics, UJT, firing circuits.

1-Phase, semicontrolled and fully controlled rectifiers, Performance factors.

UNIT 2: 3-PHASE RECTIFIER

3-Phase rectifiers: Full wave bridge type, Zig-zag and six phase configuration, Effect of load and source inductances.

UNIT 3: SCR COMMUTATION TECHNIQUES AND DC-CHOPPER SCR commutation techniques, step up and step down operation.

UNIT 4: DC MOTOR CONTROL

DC Motor Control: Armature and field control of speed of dc motors, Braking.

Dual Converter: Circulating and non-circulating current types.

UNIT 5: INVERTERS

Half bridge and full bridge inverters. PMW operation, Principle of induction motor speed control.

SUGGESTED READINGS:

MH Rashid: POWER ELECTRONICS J Vithyathil: POWER ELECTRONICS

MS Berde: THYRISTER ENGINEERING MD Singh: POWER ELECTRONICS

N Mohan: POWER ELECTRONICS

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Course Number: EEM606, Course Title: POWER ELECTRONICS LAB.

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session 2015-16 Total Credits:1.5, Total pds.(55 mts each)/week: 3(L:0+T:0+P:3+S:0)Min. pds./sem.: 39 1. Design UJT trigger circuit for half wave, rectifier operating at 5 KHz.

2. Design UJT trigger circuit for full wave rectifier operating at 5 KHz.

3. To plot VI characteristic of SCR and determine its dv/dt limit.

4. Design a DC chopper using class-B commutation.

5. Design a DC chopper using MOSFET IRF 840.

6. Design a trigger circuit for single phase ac voltage controller.

7. Design a 1 series inverter.

8. Design 1 inverter using MOSFETS.

Course Number: EEM608, Course Title: CONTROL ENGINEERING

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session 2015-16 Total Credits:2, Total pds. (55 mts each)/week: 2(L:2+T:0+P:0+S:0)Min. pds./sem.: 26

UNIT 1: INTRODUCTION [6]

Equation of Physical Systems: Modelling of translation of first and second order systems.

UNIT 2: TIME DOMAIN RESPONSE AND STABILITY [5]

Transient response of first and second order systems to standard inputs.

Stability: Routh-Hurwitz criterion.

UNIT 3: FREQUENCY RESPONSE [5]

Bode plots. Gain and phase margin. Elementary concepts of Nyquist criterion.

UNIT 4: ROOT LOCUS [4]

Construction of root loci.

UNIT 5: CONTROL SYSTEM COMPONENTS [6]

DC Motors. DC and AC servo motors. Synchro transmitter and Receiver pair. Potentiometers.

Hydraulic servo motion and Hydraulic Amplifiers. Principles of operation and transfer function of the above components. Preliminary ideas of compensation.

SUGGESTED READINGS:

Ogata: CONTROL ENGINEERING Kuo: AUTOMATIC CONTROL SYSTEMS Norman Nise: CONTROL SYSTEMS

Course Number: EEM609, Course Title: STREAM SEMINAR

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2009-10 Total Credits:1, Periods(55 mts. each)/week: 2(L:0+T:0+P:0+S:2), Min.pds./sem.: 26 Stream Seminar course.

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Course Number: EEM611, Course Title: DESIGN & ANALYSIS OF ALGORITHMS Class: B.Tech., Status of Course: MAJOR, Approved since session: 2015-16

Total Credits:3, Total pds.(55 mts each)/week: 3(L:3+T:0+P:0+S:0) Min. pds./sem.: 39 UNIT 1: INTRODUCTION

Algorithms, analysis of algorithms, Growth of Functions, Master Theorem. Sorting and order Statistics: Heap sort, Quick sort, Sorting in Linear time, Medians and Order Statistics.

UNIT 2: ADVANCED DATA STRUCTURES

Red-Black Trees, Augmenting Data Structures. B-Trees, Binomial Heaps, Fibonacci Heaps, Data Structure for Disjoint Sets.

UNIT 3: ADVANCED DESIGN AND ANALYSIS TECHNIQUES Dynamic Programming, Greedy Algorithms, Amortized Analysis.

UNIT 4: GRAPH ALGORITHMS

Elementary Graphs Algorithms, Minimum Spanning Trees, Single-source Shortest Paths, All-Pairs Shortest Paths, Maximum Flow, Travelling Salesman Problem.

UNIT 5: SELECTED TOPICS

Randomized Algorithms, String Matching, NP Completeness, Approximation Algorithms.

SUGGESTED READING:

Cormen, Leiserson, Rivest: “INTRODUCTION TO ALGORITHMS”, PHI.

Basse, S.: “COMPUTER ALGORITHMS: INTRODUCTION TO DESIGN & ANALYSIS”, Addison Wesley.

Horowitz & Sahani, “FUNDAMENTAL OF COMPUTER ALGORITHMS”, Galgotia.

Course Number: EEM612, Course Title: COMPUTER SCIENCE LAB.

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2009-10

Total Credits:1.5, Total pds. (50 mts each)/week: 3(L:0+T:0+P:3+S:0) Min. pds./sem.: 39 Programming assignments on each algorithmic strategy:

1. Divide and conquer method (quick sort, merge sort, Strassen’s matrix multiplication).

2. Greedy method (knapsack problem, job sequencing, optimal merge patterns, minimal spanning trees).

3. Dynamic programming (multistage graphs, OBST, 0/1 knapsack, traveling salesperson problem).

4. Back tracking (n-queens problem, graph coloring problem, Hamiltonian cycles).

5. Sorting and Searching: Programming various searching and sorting algorithms.

6. Selection: Minimum/Maximum, kth smallest element.

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Course Number: FEM601 Footwear Pattern Design And Grading System

Class: B.Tech.(Footwear Technology), Status of the Course: MAJOR, Approved Session: 2014-15 Credits: 3, Periods (55 mts. each) per week: 3 (L:3+T:0+P:0), Min. Periods/Sem.: 39

This course aims to provide knowledge and skills to students that is required to apply the principle Footwear Pattern Design, Grading System and its place in the manufacturing process. It is also provide the knowledge in the production of pullover and shoe models.

UNIT - 1 INTRODUCTION

Selection of footwear by consumer’s Age, Sex, Comfort, aesthetics, profession etc. Influence of climatic conditions. Different size system, difference between human foot and shoe making last, variation between Right and Left foot sizes,

UNIT – 2 Selection of last

Selection of last depending on smartness, comfort and elegance. Location of points on last (Center Line, joints and vamp point), Making on last (Center line, front, back, tread line), chappal and sandal Pattern, Preparation of insole and sole pattern of shoe.

UNIT – 3

Preparation of section pattern for upper and lining for various designs, Oxford, Derby, Monk, Casuals with and without elastic, Grescion, Ankel Boot, Long Boot, Court Shoe. Pattern Making:

tools and machinery, materials on which pattern are cut, Difference between plastic and wooden last, storage of pattern.

UNIT – 4

Alteration of last according to foot measurements, With special emphasis on foot deformation and orthopedics problems.

Preparation of patterns of bottom components, computer aided footwear designing pattern making

& pattern cutting, Graphic system to find correct area of patterns.

UNIT – 5 Grading

Principles of Grading, Grading Methods such as by hand, pantograph, geometrical, comparative and radial tools system, Grading with the help of computer, Pattern nesting and grading.

SUGGESTED READINGS:

Harvey, A.J., “Footwear Materials and Process Technology”, LASRA Publications, New Zealand, 1982.

S.N. Gongly, ‘Comprehensive footwear technology”

Course Number: FEM605 Leather Goods and Garments Manufacturing

This course aims to describe and develop awareness on the essentials for Leather Goods and Garments Manufacturing.

UNIT - 1 INTRODUCTION

Classification of leather garments based on design, usage, fashion; principles of tailoring, Types of leather used in garments, Properties of garment leather.

UNIT – 2

Designing of leather garments and preparation of sectional patterns, Minimization of Leather wastage, Designing and Fabrication of gloves, headwear, sports goods such as football, hokey and cricket ball.

UNIT – 3 Machinery and equipments

Machinery and equipments for leather goods and garments such as sewing machine, button hole and button stitching machines, ironing press.

Tools: gimping, scissors, wooden and iron hammers, stone slab, measuring tapes, cryons etc.

Dummies for checking fittings.

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Course Number: FEM605 Finishing and Packaging Technology

All the products manufactured or processed are packed in some way or other. With trade barriers vanishing, export has increased which further demand more and more packaging. Packaging is a very competitive field. It embraces various disciplines of science and technology. With the increasing importance of packaging and its growth, it is necessary for footwear students to learning about finishing and packaging.

UNIT - 1 Finishing

Object of Finishing – Types of finishing, Different finishing procedure for different types of footwear.

Materials used in finishing, Inspection of complete shoe.

UNIT – 2 Packaging

Definition, Importance and process of packaging. Types of Packaging,

Description of packaging material and packaging techniques, Package components. Export Packaging, Transit Hazards – Road, Rail, & Air- Test Procedures for Evaluation of Transport – worthiness.

UNIT – 3 Tests

Tests, Testing equipment and requirements of packaging materials, Environmental issues.

Mechanisms of Spoilage,Cushion Design and Prevention of shock Damage. Corrosion prevention in packaging.

UNIT – 4 Packaging machines, Printing and Labeling

Different packaging machines, Printing and Printing Machines, Labels and Bar Coding.

UNIT – 5 Branding and Launching

Definition, Importance and process of Branding. Product Development, Launching of new Product.

SUGGESTED READINGS:

Better Packaging, Better World, Instituto de Embalagens - Brazil.

Walter Soroka, Fundamentals of Packaging Technology-Fourth Edition Hand Book of Packaging Technology, ISBN – 8186732670

S Natarajan , M Govindarajan , B Kumar, Fundamentals of Packaging Technology, Jain Book Depot.

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Course Number: MEM601, Course Title: MECHANICAL ENGINEERING DESIGN I Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session-2013-14 Total Credits:4, Periods(55 mts. each)/week: 4(L:4+T:0+P:0+S:0), Min.pds./sem.: 52 UNIT 1: DESIGN FUNDAMENTALS

Selection of Materials - Existing materials including advanced materials like composites, etc., their properties, some case studies in material selection, material selection based on job requirements.

General considerations in design. Axial retainment of rotating parts.

UNIT 2: JOINTS, SHAFTS, KEYS & COUPLINGS

Joints for axial loads: Cotter joints. Knuckle joints. Adjustable screw joint (turnbuckle). Riveted joints. Screwed connections. Eccentrically loaded bolted, riveted and welded joints.

Shafts, Keys and Couplings: Shaft, key Design. Rigid couplings, Flexible (compliant) couplings.

UNIT 3: STRESS CONCENTRATION AND FATIGUE

Stress concentration, Geometric stress concentration factors, Methods of reducing stress concentration. Fatigue. Endurance limit, fatigue strength. S-N diagrams. Notch sensitivity. Life estimation. Modified Goodman diagrams. Design aspects.

UNIT 4: LEVERS & BELT DRIVES

Levers: Hand lever, foot lever, cranked lever. Bell crank lever. Rocker arm. Lever of a lever safety valve.

Belt drives: Belt, rope and chain drives. Hoisting machine elements. Pulleys, Flywheels.

UNIT 5:Brakes and Clutches

Introduction, Types, Materials. External shoe brakes. Block brakes. Double shoe block brakes.

Internal shoe brakes. Band brake. Band and block brake. Single and multiple disk clutches. Cone clutch. Centrifugal clutch.

SUGGESTED READING:

Lewis: SELECTION OF ENGINEERING MATERIALS Bhandari: DESIGN OF MACHINE ELEMENTS Sharma & Agarwal: MACHINE DESIGN Shigley: MECHANICAL ENGINEERING DESIGN Pandya & Shah: MACHINE DESIGN

RL Norton: MACHINE DESIGN: AN INTEGRATED APPROACH

Course Number: MEM602, Course Title: MECHANICAL ENGG. DESIGN PRACTICE I Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session-2006-07 Total Credits:2, Periods(55 mts. each)/week: 4(L:0+T:0+P:4+S:0), Min.pds./sem.: 52 1. Knuckle Joints

2. Cotter Joints

3. Big end of connecting Rod 4. Flange coupling

5. Flexible flange coupling 6. Cranked lever

7. Rocker Arm 8. Screw clamp

9. CAD: Solids Works Software

Note: Atleast 4 sheets be prepared using Solid Works Software & 1 or 2 sheets in the normal way.

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Course Number: MEM603, Course Title: METAL CUTTING & TOOL DESIGN Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session-2013-14 Total Credits:3, Periods(55 mts. each)/week: 4(L:3+T:1+P:0+S:0), Min.pds./sem.: 52

UNIT 1: MECHANISM OF METAL CUTTING

Deformation of metal during machining. Nomenclature of single and multiple cutting tools.

Mechanism of chip formation. Built-up edges. Mechanics of orthogonal and oblique cutting. Cutting forces. Factors affecting tool force, cutting speed, feed and depth of cut. Surface finish. Power requirement. Temperature distribution at tool chip interface.

UNIT 2: TOOL WEAR AND MACHINABILITY

Theories of wear. Cutting fluids. Basic action of cutting fluid. Tool life. Factor governing tool life.

Machinability. Definitions and evaluation.

ECONOMICS OF METAL MACHINING: Single and multipass machining operations. Criteria variable and restrictions for selecting economical conditions.

UNIT 3: MULTIPOINT TOOLS

Design considerations. Power and force requirements for drilling, milling, Linear travel tools- broaches. Chatter and its significance. Surface roughness.

CASTING DESIGN: Application of theory of gate and riser design to actual casting. Application of design consideration to casting.

UNIT 4: PRESSES AND PRESS TOOL DESIGN

PRESSES: Classification, specification, selection of Presses. Blanking. Piercing. Bending. Drawing and Deep Drawing. Progressive dies. Compound dies. Force requirements for blanking, Piercing and bending. Selection of die set. Die block. Metal flow in drawing. Single and double action dies.

Reduction factor.

UNIT 5: JIGS & FIXTURES

Design Principles. Principles of location. Locators & clamps. Hydraulic & pneumatic clamping devices. Jig bushing. Types and design of drilling jigs & fixtures. Poka Yoke - fool proofing and concepts around fool proofing.

SUGGESTED READING:

MACHINING OF METALS: Armarago & Brown

PRINCIPLES OF MACHINE TOOLS: G.C. Sen & A. Bhattacharya PROCESSES AND MATERIALS OF MANUFACTURE: Roy A. Lindberg MANUFACTURING SCIENCE: P.C. Sharma

Course Number: MEM604, Course Title: PRODUCTION ENGINEERING LAB.

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session-2000-01 Total Credits:1, Periods(55 mts. each)/week: 2(L:0+T:0+P:1+S:1), Min.pds./sem.: 26 1. Determination of Mould and Core hardness.

2. Determination of Permeability of a given Sand Sample using Permeability Tester.

3. Determination of grain fineness number of a given Sand Sample using Shieve Shaker.

4. Determination of shear plane angle of given sample on Lathe machine 5. Determination of Machinability index of samples on drilling machine.

6. Determination of force & torque in given samples using drilling dynamometer.

7. Determination of forces in given samples using milling tool dynamometer.

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Course Number: MEM605, Course Title: HEAT TRANSFER

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session-2013-14 Total Credits:3, Periods(55 mts. each)/week: 4(L:3+T:1+P:0+S:0), Min.pds./sem.: 52 UNIT 1: INTRODUCTION & CONDUCTION

Modes of heat transfer. Conduction, convection and radiation, Mechanism of thermal conduction in solids, liquids and gases, Convection and heat transfer coefficient. Radiation.

CONDUCTION: Fourier’s law, Thermal conductivity of solids, liquids and gases. Factors influencing thermal conductivity, General three dimensional heat conduction equation in Cartesian and cylindrical co-ordinates. One-dimensional steady state conduction, Heat flow through composite plane wall, cylinder and sphere, Heat source systems, plane wall and cylinder, Critical thickness of insulation.

UNIT 2: CONDUCTION (contd.)

Heat dissipation to environment, Different types of fins. Heat transfer from fins of uniform cross- section, Solution by relaxation technique.

Two dimensional steady state conduction through plane wall, One-dimensional unsteady state, lumped heat capacity systems. Heat flow in semi-infinite solid with sudden change of surface temperature. Heating and cooling of bodies with negligible resistance.

UNIT 3: CONVECTION

Forced convection, Basic concepts of hydrodynamic and thermal boundary layers, momentum equation and its solution for hydrodynamic boundary layer over a flat plate, Energy equation and its solution for thermal boundary layer over a flat plate, thickness of thermal boundary layer, heat transfer coefficients in forced convection. Similarity conditions of heat transfer processes, Application of dimensional analysis, Empirical equations of force convective heat transfer for plate and cylinder.

Free convection: Physical mechanism, application of dimensional analysis, Similarity conditions of heat transfer processes, empirical equations of free convective heat transfer for plate and cylinder.

Fundamentals of boiling heat transfer. Pool boiling, Heat transfer in condensation, Drop wise and film condensation, Empirical equations.

UNIT 4: RADIATION

Thermal Radiation, Monochromatic and total emissive power, Absorptivity, reflectivity and transmissivity in black, grey and real surfaces, Plank’s distribution law, Wien’s displacement law, Stefan-Boltzmann’s law, Kirchoff’s law

Heat transfer by radiation between black surface and grey surface, Heat transfer in presence of re- radiating surfaces, Electrical network method of solving radiation problems, Radiation shields.

Shape factor.

UNIT 5

HEAT EXCHANGERS: Basic types of heat exchangers. Fouling factor, Overall heat transfer coefficient, Logarithmic mean temperature difference. Effectiveness, NTU methods of design of single and multiple pass heat exchangers

RECENT / INDUSTRIAL APPLICATIONS: Flat plate Heat Exchanger, Heat Pipe, cooling of electronic equipment, microscale heat transfer, super insulation (for spacecrafts etc)

SUGGESTED READING:

Kreith: PRINCIPLES OF HEAT TRANSFER Gupta and Prakash: ENGINEERING HEAT TRANSFER

Mikhiyeo: FUNDAMENTALS OF HEAT TRANSFER Holman: HEAT TRANSFER

Eckert and Drake: HEAT AND MASS TRANSFER Domkundwar: HEAT TRANSFER

Frank P Incropera & David P DeWitt: FUNDAMENTALS OF HEAT & MASS TRANSFER Course Number: MEM606, Course Title: HEAT TRANSFER LAB.

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session-2000-01 Total Credits:1, Periods(55 mts. each)/week: 2(L:0+T:0+P:1+S:1), Min.pds./sem.: 26

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Course Number: MEM607, Course Title: AUTOMOBILE ENGINEERING

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2013-14 Total Credits:3, Periods(55 mts. each)/week: 4(L:3+T:1+P:0+S:0), Min.pds./sem: 52 UNIT 1: S.I. AND C.I. ENGINES

Comparison of S.I. and C.I. engines. Performance curves. Inline, L.,T,F, and I head type engines.

Constructional details with material and function of different parts (cylinder, piston, piston rings, wrist pin, connecting rod, crank shaft and bearing). Piston side thrust. Cylinder wear. Constant clearance pistons. Fixing methods of wrist pin. Mufflers. Cold starting and various other methods of starting.

Fuel Feed Systems and Carburettors: Gravity. Auto-Vac (Stewart Vaccum Feed System) and Pressure Feed System. Filters. Fuel gauges. Fuel pump. Relief Valve. Electronic fuel injection in SI engines.

UNIT 2: LUBRICATION, COOLING & ELECTRICAL SYSTEM

Lubrication and Cooling: Splash, Pressure Feed (wet and dry sump). Oil pumps (rotary gear and plunger). Crank case dilution. Filters. Air, water and evaporative cooling. Thermostat. Instrumental panel. Temperature indicator. Anti-freeze mixtures.

Electrical System: Battery. Its charging and care. Various Ignition systems. Ignition timings.

Ignition advance and retard devices. Spark plug. Firing order determination. Cut-out and voltage current regulators. Starting and lighting systems. Electric horn. Trafficators.

UNIT 3: CHASIS AND TRANSMISSION

Chassis and Transmission: Transmission requirements. Transmission layout.

Chassis: Types of frames. Chassisless construction.

Clutch: Requirements of clutch. Various types of clutches. Automatic clutch. Pedal play. Adjustment of clutch.

Gear Box: Object of gear box. Constant mesh, synchromesh and epicyclic (pre-selective) gear box.

Over drive. Free-wheeling device.

UNIT 4: DRIVES

Drives: Hotchkins and torque tube drives. Torque reaction. Universal joint. Differential gear.

Principle of fluid, Hydro-matic and Dyna-flow drives.

Axles and Steering Mechanism: Front wheel suspension (conventional leaf spring and independent).

Principle of steering. Steering requirements. Steering geometry. Davis and Ackerman Steering.

Steering layout. Steering boxes (screw and nut, worm and wheel and cam and level types). Wheel alignment (caster & camber angle, toe-in, toe-out on turn, king-pin inclination)

UNIT 5: BRAKING SYSTEM

Braking system: Motor vehicle brake. Classification. Mechanical and hydraulic brakes. Air assisted brakes, vacuum brakes. Band Brake. Hand brake. Engine as brake.

Wheels and Tyres: Types of tyres (Pneumatic, steel and solid). Types of rims (spoke, detachable and non-detachable). Effect of wheel alignment and inflation on tyre wear. Tyre rotation.

General: Clearance and setting data (Tappet clearance. C.B. gap. Spark plug gap. Piston ring gap.

Piston clearance and backlash in gears). Repair shop. Service station and garage equipment for maintenance, repair and overhaul.

SUGGESTED READINGS:

Joseph Heitner: AUTOMOTIVE MECHANICS Newton & Steeds: MOTOR VEHICLE

KM Gupta: AUTOMOBILE ENGINEERING (Vol.I & II) RB Gupta: AUTOMOBILE ENGINEERING Course Number: MEM608, Course Title: AUTOMOBILE ENGINEERING LAB.

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2013-14 Total Credits:1.5, Periods(55 mts. each)/week: 3(L:0+T:0+P:3+S:0), Min.pds./sem: 39 Based on the Theory course.

Course Number: MEM609, Course Title: STREAM SEMINAR

Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2009-10 Total Credits:1, Periods(55 mts. each)/week: 2(L:0+T:0+P:0+S:2), Min.pds./sem.: 26 Stream Seminar course.

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Course Number: MEM611, Course Title: STATISTICAL QUALITY CONTROL Class: B.Tech., Status of Course: MAJOR, Approved since session: 2013-14

Total Credits:3, Periods(55 mts each)/week: 4(L:3+T:1+P:0+S:0), Min. pds./sem.: 52 UNIT 1: INTRODUCTION AND STATISTICAL METHODS

Historical Evolution of SQC. Meaning and Management of Quality. Dimensions of Quality. Link between Quality and Productivity. Quality Costs. Statistical Methods: Histogram, Frequency diagram, Tally Sheet, Bar Chart. Mean, Median, Mode, Standard Deviation, Variance. Probability Distributions: Poisson, Binomial, Geometric, Hypergeometric, Exponential, Gamma, Weibull and Normal Distributions. Estimation of parameters.

UNIT 2: CONTROL CHART TECHNIQUES

Statistical basis of Shewhart Control Charts. Control Charts for Variables: Development and use of x-bar, R, and S charts. Control Charts for Attributes: Development and use of Fraction non- conforming (p), Number of nonconformities (c), and Number of nonconformities per unit (u).

Choice between Variable and Attribute Charts.

UNIT 3: ACCEPTANCE SAMPLING

Fundamentals. Basis and development of Operating Characteristic (OC) Curves. AQL & AOQL. Type A and Type B OC Curves. Single Sampling Plan. Double Sampling Plan. Multiple and sequential sampling plan. Dodge – Roming Plan for Lot by Lot Acceptance Sampling for Attributes.

UNIT 4: RELIABILITY AND LIFE TESTING

Reliability defined. Reliability of a System. Reliability as a function of Time. Exponential Model in Reliability. Mean Time Between Failure (MTBF). Life Testing and Reliability.

UNIT 5: QUALITY ASSURANCE

Quality Planning, Quality of Design, Quality of Conformance. Contributions of Juran, Deming, Crosby, Ishikawa, Taguchi, and Feighbaum.

SUGGESTED READINGS:

EL Grant: STATISTICAL QUALITY CONTROL, McGraw Hill, NY, 1988.

JM Juran & FM Gryna: QUALITY PLANNING AND ANALYSIS, III Ed., McGraw Hill, ND, 1995.

DC Montgomory: STATICTICAL QUALITY CONTROL: A MODERN INTRODUCTION, John Wiley, 2009.

Course Number: MEM612, Course Title: STATISTICAL QUALITY CONTROL LAB.

Class: B.Tech., Status of Course: MAJOR, Approved since session: 2009-10

Total Credits:1.5, Total pds. (55 mts each)/week: 3(L:0+T:0+P:3+S:0), Min. pds./sem.: 39

1. Determine Producer’s and Consumer’s Risk and draw the operating Characteristic curve (OCC).

2. Draw the Control charts for Variables for the given data. Also compare the primary and revised control limits.

3. Draw the control charts for the attributes for the given data and check the validity.

4. For the data available on a sample of a company perform the following tests for the given data:

(a) Whether the process is in a state of statistical control?

(b) Assuming that assignable causes could be discovered and eliminated for all points showing the process to be out of control, what is your best estimate to the capability of the process?

5. In a single sampling plan, draw the operating characteristic of the sampling plan and determine the producer and consumer’s risk at various % defectives and draw the AOQ curve of this plan with different % defectives.

6. Compute and construct p chart for the given data showing 3 Sigma limits and comment on

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Course Number: MAM681, Course Title: ADVANCED OPTIMIZATION TECHNIQUES Class: B.Tech., Status of Course: MAJOR COURSE, Approved since session: 2002-03 Total Credits:3, Periods(55 mts. each)/week: 4(L:4-0+P:0+S:0), Min.pds./sem: 52

UNIT 1 [10 pds]

Introduction to general linear programming problems, Geometrical and Algebraic analysis of models/ solutions. Definitions and Theorems, solution of L.p.p.-graphical, simplex, two-phases of simplex, Big-M method.

UNIT 2 [10 pds]

Concept of Duality: Primal/Dual relationship Theorems, Dual-simplex, Post-optimality analysis, Transportation Problems. Assignment Problem and Routeing Problem.

UNIT 3 [10 pds]

Non-linear programming problems: Lagrange's method, Kuhn-Tucker conditions, Graphical Method, Fibonacci and Golden section search, Concept of Quadratic programming, Steepest Descent Method, Conjugate metric method, Frank-Wolfe method.

UNIT 4 [10 pds]

Dynamic Programming: Multistage decision processes, Concept of sub-optimality, Principle of optimality, Calculus method of solution, Tabular method of solution, L.p.p. as a case of Dynamic programming.

UNIT 5: INTEGER PROGRAMMING [10 pds]

Gomory method for pure and mixed LPP, All pure and mixed integer programming, Algorithm and solution of numerical problems, Branch and bound method.

SUGGESTED READINGS:

G Hadley: LINEAR PROGRAMMING SI Gass: LINEAR PROGRAMMING SS Rao: OPTIMIZATION TECHNIQUES

NS Kambo: MATHEMATICAL PROGRAMMING TECHNIQUES MA Taha: OPERATIONS RESEARCH

KV Mittal: OPTIMIZATION METHODS

Course Number: FCM601 Course Title: BASIC MARKETING

Class: B. TECH-B.COM., Status of Course: MAJOR, Approved since session: 2016-17 Total Credits: 3, Periods (55 mts. each)/week: 4 (L-4+T-0+P/S-0), Min.pds./sem:52 UNIT 1: INTRODUCTION

Nature, Scope, Evolution and Importance, Marketing concepts & Environment, Marketing Mix, Marketing segmentation

UNIT 2: CONSUMER BEHAVIOUR

Types of Buyers, Factors effecting Consumer Behaviour. Buying Models UNIT 3: PRODUCT PLANNING

Concept of Product, Product development, Product line, Product mix, Product Life Cycle, Product Branding and Packaging.

UNIT 4: CHANNELS OF DISTRIBUTION

Types of Middle Men and its Functions Factors effecting selection of channel, Physical distribution, Channel conflicts

UNIT 5: PRICING AND PROMOTION DECISIONS

Pricing Policy, Forms of Promotion, Advertising, Personal Selling, Sales Promotion and Public Relations, After Sales Services.

SUGGESTED READINGS:

Davar: MANAGEMENT PROCESS IN SUGGESTED READINGS:

Kotler Phillip: PRINCIPLES OF MARKETING

Gandhi JC: MARKETING-A MANAGERIAL APPROACH Clarke: PRINCIPLES OF MARKETING

Sherlekar: MARKETING MANAGEMENT MARKETING

Mamoria CB: THE PRINCIPLES AND PRACTICE OF MARKETING Sharma SL: MARKETING MANAGEMENT

Srivastava PK: VIPRAN PRABANDH (HINDI) Srivastava PK: MARKETING MANAGEMENT Ramaswamy & Nama Kumar: BASIC MARKETING

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Course Number: FCM602 Course Title: BUSINESS INSURANCE

Scope and functions, various forms of Insurance, fundamental principles of Insurance. IRDA – introduction and important provisions

UNIT 2: MARINE INSURANCE

Essentials of Marine Insurance Contracts, Types of policies UNIT 3: FIRE INSURANCE

Essentials of Fire Insurance Contracts, Types of policies Unit 4: LIFE INSURANCE

Essentials of Life Insurance Contracts, Factors effecting in determination of Premium, Classification of Life Insurance Policies

UNIT 5: MISCELLANEOUS INSURANCE

Motor Insurance, Personal Accident Insurance, Aviation Insurance, Engineering Insurance SUGGESTED READINGS:

Kothari & Bahal: PRINCIPLES & PRACTICE OF INSURANCE Mishra MN: INSURANCE-PRINCIPLES & PRACTICE

Mitra JC: GUIDE TO MARINE FIRE & ACCIDENT INSURANCE Srivastav & Balchand: ELEMENTS OF INSURANCE (HINDI) Kamta Prasad: PRINCIPLES & PRACTICE OF INSURANCE (HINDI) Anand Kumar: PRELIMINARY ELEMENTS OF INSURANCE (HINDI)

Course Number: FCM603, Course Title: ENTREPRENEURSHIP

Concept of Entrepreneur, Entrepreneurship and Entrepreneur, Entrepreneur vs. Manager;

Significance of Entrepreneurship in Economic Development; Qualities, and Functions of

Entrepreneur; Ethics and Entrepreneurship; Life Cycle of new Business and relationship with Large Enterprises.

UNIT 2: CREATING ENTREPRENEURIAL VENTURE

Business Plan as Entrepreneurial Tool : New product, Franchising, Partial Momentum, Sponsorship and Acquisition, Legal aspect to organizing business, Environmental Factors affecting success of a new Business; Reasons for the failure and visible problems for Business.

UNIT 3: PROJECT MANAGEMENT

Feasibility Study -Preparation of Feasibility Reports: Location, Economic, Technical, Marketing and Managerial Feasibility of Project. Estimating and Financing funds requirement, Schemes of financial institutions Like Commercial Banks, IDBI, ICICI, IFC, SFC, SIDBI, Venture Capital Funding.

UNIT 4: ENTREPRENEURSHIP AND GOVERNMENT

Role of Central and state Governments, Government support to new Enterprise; Entrepreneurship Development Programs; Role of various institutions in Developing Entrepreneurship in India: DICs, Small Industries Service Institute, Entrepreneurship Development Institute of India (EDII), National Institute of Entrepreneurship & Small Business Development (NIESBUD) National Entrepreneurship Development Board (NEDB).

UNIT 5: ENTREPRENEURSHIP FOR INCLUSIVE GROWTH ROLE, PROBLEMS & PROSPECTS

Rural Entrepreneurship, Entrepreneurship for MSME, Women Entrepreneurship, Microfinance and Micro insurance.

SUGGESTED READINGS:

Cliffon, Davis S and Fyfie, David E., Project Feasibility Analysis, John Wiley Desai, A N., Entrepreneur & Environment., Ashish Publications