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SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 1
SCHOOL OF ENGINEERING PROGRAM : M.TECH – Structural Engineering
ADMISSION YEAR - 2018-2020 SEMESTER – II
DEFINATION OF ONE CREDIT :
1. Lecture (L): 1 hour / week / semester, 2. Practical (P): 2 hour / week / semester3. Tutorial(T): 2
hour / week / semester
TEACHING SCHEME
Course
Code Course Name
Teaching Hours Cred
its
Audit
cour
se
CI
E
PS
EE
Remar
ks if
any Lectu
re
Tutori
al
Practi
cal
SE201 Structural Dynamics and Earthquake
Engineering 4 0 2 5 N Y Y
SE202 Finite Element Method 3 2 0 4 N Y Y
SE211 Advanced Design of Steel Structures 4 2 0 5 N Y Y
SE204 Seminar 0 0 0 5 N Y Y
Elective II 3 0 2 4 N Y Y
Elective III 3 2 2 4 N Y N
Total 17 6 04 27
Total Hours 27
List of Elective-II Subjects
SE205 Advanced Foundation
Engineering
SE 210 Wind effects on structures
List of Elective- III Subjects
SE206 Design of Masonry Structures
SE207 Structural Optimization
SE208 Design of Bridges
SE 209 Theory of plates & shells
N- No CIE – Continuous internal evaluation
Y – Yes PSEE – Practical semester end examination including ITD, Dissertation, Industrial project, Industrial training etc.
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 2
Course Title STRUCTURAL DYNAMICS AND EARTHQUAKE ENGINEERING
Course Code SE201
Course Credit
Theory :04
Practical :02
Tutorial :00
Credits :05
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Understand various terminologies related to dynamic analysis of structural system
Analyze single degree of freedom system (SDOF) through free & forced vibration
Determine natural frequencies and mode shapes of multi degree of freedom system (MDOF)
Understand causes, types and measurement of an earthquake
Develop response spectrum for earthquake ground motion
Estimate lateral load on the structures as per codal stipulations
Analyze and design various lateral load resisting systems
Appraise concept of ductility and related codal specification for earthquake resistant design
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Introduction to Dynamics
D Alembert’s Principle , Basic Definition, Free Vibration & Forced vibration for
Damped , Undamped and Critically Damped Systems, Coulumb Damping , Energy
Method, Harmonic Loading , Rotating Unbalance , Transmissibility and
Logarithmic Decrement for SDF System and Numerical Methods ( Direct
Integration Technique)
07
2. Two and Multi Degrees of Freedom System
Introduction, Free Vibration and Forced vibration Undamped and Damped TDSs,
Orthogonality. Eigen Values and solutions , Holzer Method , Stodola Method
Rayleigh Ritz Method Lagrange Equation, Response of MDF , Damping in MDF
Earthquake Spectrum Analysis
07
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 3
3. Free and Forced vibration in Continous System
Vibration of Strings, Free and Forced Vibration of Bars (Longitudinal and
Flexural). 07
Total 21
SECTION-II
4. Introduction to Seismic Resistant Design : Basic Definition, Magnitude and Intensity, Zones, Case Studies, IS 1893 Clauses,
Soft Storey, Causes of Earthquake and Characteristics 06
5. Earthquake resistant design
Philosophy, Analysis and design of lateral load resisting systems - M R Frame,
Shear Wall & Bracing. Ductility, Codal provision and Ductility based design of
Beam & Column, Lateral load evaluation by modal superposition analysis as per
IS:1893 and codal provisions, Modal analysis of building systems
10
6. Special Techniques
Introduction to earthquake geotechnical aspects, Introduction to Base Isolation
System & Damping Devices. Seismic response control concepts – Seismic demand,
seismic capacity, Overview of linear and nonlinear procedures of seismic analysis.
Performance Based Seismic Engineering methodology, Seismic evaluation and
retrofitting of structure
05
Total 21
Term Work: Term work shall be based on the above mentioned course content.
Instructional method and Pedagogy:
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP etc.
2. Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an appreciation
for the concepts being taught in lectures.
Reference Books:
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 4
1. Dynamics of Structures‖, McGraw Hill, Kogokusha
2. Mario Paz, ―Structural Dynamics-Theory and computaitons‖, 2/e/1999, CBS Publishers.
3. MukhopadhyayMandhujit, ―Vibrations, Dynamics and Structural Systems‖, Oxford and
IBH, 1/e/2000
4. Chopra Anil K., ―Dynamics of Structures- Theory and Applications to Earthquake
Engg.‖, Prentice Hall, India, 2/e/2002
5. Pankaj Agrawal, Manish Shrikhande, Earthquake Resistant Design of Structures,
Prentice-Hall of India.
6. IS Codes : IS:1893, IS:4326, IS:13920, IS:13828, IS:456t
7. Earthquake Resistant Design of Building Structures, Vinod Hosur, WILEY (India)
8. Earthquake Resistant Design of Structures, Duggal, Oxford University Press 4.
Earthquake resistant design of structures - Pankaj Agarwal, Manish Shrikande - PHI India
Additional Reference N.P.T.E.L lecture series
Prof. P Banerji IITB http://nptel.ac.in/courses/105101006/1
List of Experiments 1. To determine the dynamic response of spring mass model.
2. To determine the dynamic response through mode shapes of a building.
3. To determine the lateral load resistance due to shear wall.
4. To determine the lateral load resistance by provision of bracing.
5. To determine the effect of pounding between adjacent structures.
6. To determine and evaluate the dynamics of three storied building frame subjected to
harmonic base motion
7. To the dynamics of one-storied building frame with planar asymmetry subjected to
harmonic base motion
8. To determine and evaluate study the dynamics of three storied building frame subjected to
periodic (non-harmonic) base motion.
9. To determine and evaluate the vibration isolation of secondary beam.
10. To determine the dynamics of one span and two span beams.
11. To determine and evaluate the dynamics of three storied building frame subjected to
harmonic base motion.
12. Site visit report of a RCC building with detailing
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 5
Course Title FINITE ELEMENT METHOD
Course Code SE202
Course Credit
Theory :03
Practical :00
Tutorial :02
Credits :04
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Understand different mathematical technique to solve FEM problem.
Derive to derive the shape function.
Resolve 2D equation using scalar function variable.
Understand and resolve 2D vector variable problem
Derive the shape function for isoparmetrical formulation
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Introduction:
General Description of the Method, Finite Element Method vs Classical Method,
Equations of Equilibrium, Strain Displacement Equation. Introduction to Finite
difference Methods
05
2. Elasticity
Linear elasticity; stress, strain, constitutive relations; field condition and Boundary
conditions; Description of an elasticity problem as a boundary value problem, Plane
stress, strain, axial symmetric problems. Computation of element properties using
Coordinate Systems.
07
3. One Dimensional Problems
Computation of element properties using natural coordinate systems and shape
functions, linear and quadratic bar element, beam element, discretization of
structure, Nodes as Discontinuities, Refining Mesh, Use of Symmetry Element
Aspect Ratio,
09
Total 21
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 6
SECTION-II
4. Two Dimensional Problems and Spring
Three triangular element, four noded rectangular element. Direct approach and
energy approach in spring , Rayleigh Ritz Method,
08
5. Isoparametric
Coordinate Transformation, Basic Theorems of Isoperimetric Concept,
Isoperimetric, Super parametric and Sub parametric Elements, CST Elements.
09
6. Application And Fem Packages
Pre and Post processing introduction to Analysis Software like NISA and ANSYS
etc.
04
Total 21
Term Work: Term work shall be based on the above mentioned course content.
Instructional method and Pedagogy:
5. Lectures will be conducted with the aid of multi-media projector, black board, OHP etc.
6. Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval.
7. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
8. The course includes tutorials, where students have an opportunity to build an appreciation
for the concepts being taught in lectures.
Reference Books:
1. S S Bhavikkati, ―Finite Element Analysis‖, New Age International (P) Limited, Publishers, India
Pvt. Ltd 2007.
2. Rao S.S., ―The Finite Element Method in Engineering‖, 3rd Edition, Butterworth Heinemann,
2004
3. C S Krishnamurthy, ―Finite Element Analysis‖, TATA Mc Graw Hill Edu.Pvt.Ltd., 2013
4. Desai C S& Ables J F, ―Introduction to Finite Element Method‖, 1st Edition, Van Nostrand
Reinhold, 1987.
5. Bhatti Asghar M, ―Fundamental Finite Element Analysis and Applications‖, John Wiley & Sons,
2005 (Indian Reprint 2013)
Additional Reference
N.P.T.E.L lecture series
Dr. B.N.Rao IITM https://www.youtube.com/watch?v=lbghRDnb-LQ&list=PLFA5C164D77D3B971
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 7
Course Title ADVANCE DESIGN OF STEEL STRUCTURE
Course Code SE211
Course Credit
Theory :04
Practical :00
Tutorial :02
Credits :05
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Design the connection of steel structures by bolted or welded connections.
Apply plastic method for design of beams, frames and Gable Members.
Design the Gantry and Plate Girder.
Analyse and design the industrial structures and multi-storey buildings.
Analyse and design steel tank.
Analyse and Design the Self Supporting chimney with effect of wind.
Design the Light gauge pre-engineered application.
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Design of connections:
Bolted connections: Semi rigid and rigid beam-column and beam-beam
connections. Beam and column splices. 08
2. Plastic Design:
Plastic design of continuous beams, Rigid jointed portal frames, Gable Frames 06
3. Gantry Girder and Plate Girder:
General Consideration, Design Procedure, Web Panel subjected to Bending and
Shear, Unstiffened.
Introduction to Gantry Girder, Loading Consideration and Design.
07
Total 21
SECTION-II
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 8
4. Multi Storey and Industrial building: Introduction, loading, Analysis and design for gravity and lateral forces like wind
load, earthquake loads. 08
5. Special Steel Structure:
Design of Self Supporting Chimney , Design of Base Plate , Design of Anchor
Bolts and Design of Foundation Design of Rectangular Steel Tank, 10
6. Concept of Pre- engineered buildings:
Design of compression and tension members of cold formed light gauge sections,
Design of flexural members (Laterally restrained / laterally unrestrained),
Introduction to tensegrity Structures
03
Total 21
Term Work: Term work shall be based on the above mentioned course content.
Instructional method and Pedagogy:
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP
etc.
2. Assignments based on course content will be given to the students at the end of
each unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an
appreciation for the concepts being taught in lectures.
Reference Books:
1. N. Subramanian Design of Steel Structures: Theory and Practice, Oxford
University
2. S. K. Duggal, Limit State Design of Steel Structures, Tata McGraw Hill
3. Bureau of Indian Standards, IS800-2007, IS875-1987, IS-801-1975. Steel Tables,
SP6(1)1984
4. B.C. Punmia, A.K. Jain ―Design of Steel Structures‖, Laxmi Publications, New
Delhi.
5. Ramchandra and Virendra Gehlot ― Design of Steel Structures ― Vol 1 and Vol.2,
6. Scientific Publishers, Jodhpur
7. Design of Steel Structure - Dayarathnam, P., A.H.Wheeler, 1990
Additional Resources
N.P.T.E.L. Lecture Series Dr.Damodar Maity IITG http://nptel.ac.in/courses/105103094/2
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 9
Course Title ADVANCED FOUNDATION ENGINEERING
Course Code SE205
Course Credit
Theory :03
Practical :02
Tutorial :00
Credits :04
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
To develop an understanding of the behaviour of foundations for engineering structures
and to gain knowledge of the design methods that can be applied to practical problems.
To get the ethical knowledge of the foundation design and in various types of
footings based on different soils and load criteria
To propose the type of foundation required based on the soil test reports
To implement the ideologies of the Geotechnical Engineering in the Structural designs
To bring familiarity in various types of footings based on different soils and load criteria
To roughly estimate the required parameters of structural design of foundations even
before ordering for soil testing
To understand the geometric designs of the foundations which ultimately govern the
structural designs and post construction behavior of foundations.
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Shallow Foundation:
Terzaghi's bearing capacity equation, General bearing capacity equation , Balla's &
Meyerhof's theory, Effect of water table, special footing problems, I.S. Code,
Footing pressure for settlement on sand, Soil pressure at a depth, Boussinesq's &
Westergaard methods, Computation of settlements (Immediate & Consolidation)
Permissible
08
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 10
2. Subsurface investigation:
Introduction - Objectives of soil exploration, soil samples and soil samplers, SPT,
DCPT, Geophysical Explorations, Report Writing
03
3. Pile Foundation:
Types of Piles, Estimating pile capacity by dynamic formula, by wave equation &
by static methods, Point Bearing piles, Pile loads tests, Negative skin friction,
Modulus of subgrade reaction for laterally loaded piles, Lateral resistance.Single
Pile v/s Pile Groups, Pile group consideration, Efficiency, Stresses on underlying
strata, Settlement of pile group, Pile caps, Batter piles, Approximate and exact
analysis of pile groups, I.S code.
10
Total 21
SECTION-II
4. Well foundation:
Types (open end & closed or box, pneumatic, drilled) shapes, Bearing capacity and
settlements, Determination of grip length by dimensional analysis, Design of well
foundation construction, Tilts & shifts.
06
5. Machine Foundations:
Types, Analysis and design by Barkens methods, Determination of coefficient of
uniform elastic compression, Pauw's analogy and design of a Block type M/C
foundation, I.S.I method of design, Co- vibrating soil mass.
08
6. Sheet Pile Structure: Types, Cantilever, Anchored sheet pilling , Design by Fixed
earth Method and modifications by Anderson & Techabotarioff, Anchor Braced
sheeting cofferdam , Single well cofferdams, Cellular cofferdam,
05
7. Foundations on expansive soils
Waffle slab/raft, concept of CNS layer, chemical stabilization etc 02
Total 21
Term Work: Term work shall be based on the above mentioned course content. Case study
Instructional method and Pedagogy:
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 11
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP
etc.
2. Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an
appreciation for the concepts being taught in lectures.
Reference Books:
1. Barken, D.D. " Dynamic of Bases and Foundation "
2. Peek, Hanson and Thornburn " Foundation Engineering "
3. Leaconards " Foundation Engineering "
4. Bowles " Foundation Design"
5. Rechartetal "Vibration of Soils - Foundations.
Additional Reference
N.P.T.E.L. Lecture Series Prof Kousik Deb IITK http://nptel.ac.in/courses/105105039/
Websites:
www.asce.org
www.engineeringcivil.com
List of Experiments 1. Determination of N-value using SPT
2. Determination of N-value using DCPT
3. Auger boring/sampling
4. Free swill and swell potential
5. Determination of grain size analysis
6. Determination of atterbug limit
7. Determination of shear parameter using box shear test
8. Determination of specific gravity by pycnometer bottle
9. Model test on pile driving.
10. Model pile load test.
11. Determination of moister content using different methods
12. Site investigation Report
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 12
Course Title DESIGN OF MASONRY STRUCTURE
Course Code SE206
Course Credit
Theory :03
Practical :00
Tutorial :02
Credits :04
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Understand the behaviour of masonry structure
Understand the role of masonry units, its compressive strength and failure criteria.
Design masonry walls for various loading cases as per codal provisions.
Understand the importance of ductility in structure as per IS 13920:1993.
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Introduction, Masonry units, materials and types:
Introduction, Masonry units, materials and types: History of masonry
Characteristics of Brick, stone, clay block, concrete block, stabilized mud block
masonry units – strength, modulus of elasticity and water absorption. Masonry
materials – Classification and properties of mortars, selection of mortars.
06
2. Strength of Masonry in Compression:
Strength of Masonry in Compression: Behaviour of Masonry under compression,
strength and elastic properties, influence of masonry unit and mortar characteristics,
effect of masonry unit height on compressive strength, influence of masonry
bonding patterns on strength, prediction of strength of masonry in Indian context,
Failure theories of masonry under compression. Effects of slenderness and
eccentricity, effect of rate of absorption, effect of curing, effect of ageing,
workmanship on compressive strength.
09
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 13
3. Flexural and shear bond, flexural strength and shear strength:
Flexural and shear bond, flexural strength and shear strength: Bond between
masonry unit and mortar, tests for determining flexural and shear bond strengths,
factors affecting bond strength, effect of bond strength on compressive strength,
orthotropic strength properties of masonry in flexure, shear strength of masonry,
test procedures for evaluating flexural and shear strength.
09
Total 24
SECTION-II
4. Design of load bearing masonry buildings
Permissible compressive stress, stress reduction and shape reduction factors,
increase in permissible stresses for eccentric vertical and lateral loads, permissible
tensile and shear stresses, Effective height of walls and columns, opening in walls,
effective length, effective thickness, slenderness ratio, eccentricity, load dispersion,
arching action, lintels; Wall carrying axial load, eccentric load with different
eccentricity ratios, wall with openings, freestanding wall; Design of load bearing
masonry for buildings up to 2storeys using BIS codal provisions
18
5. Earthquake resistant masonry buildings:
Introduction to ductile detailing code IS 13920: 1993, design of special confining
reinforcement, Behavior of masonry during earthquakes, concepts and design
procedure for earthquake resistant masonry, BIS codal provisions.
06
Total 24
Term Work: Term work shall be based on the above mentioned course content. Submit design
Examples
Instructional method and Pedagogy:
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP
etc.
2. Assignments based on course content will be given to the students at the end of
each unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an
appreciation for the concepts being taught in lectures.
Reference Books:
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 14
1. Structural Masonry- Henry, A.W.: Macmillan Education Ltd., 1990.
2. Brick and Reinforced Brick Structures- Dayaratnam P.: Oxford & IBH, 1987.
3. Design of masonry structures- Sinha B.P. Davies S.R.: E&FN spon 1997.
4. IS 1905–1987 ―Code of practice for structural use of un-reinforced masonry- (3rd
revision) BIS, New Delhi.
5. SP 20 (S&T) – 1991, ―Hand book on masonry design and construction (1st revision) BIS,
New Delhi.
6. IS 13920:1993 ―Ductile detailing of reinforced Concrete structures subjected to Seismic
forces — code of practice‖.
7. NICEE publications
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 15
Course Title Structural Optimization
Course Code SE207
Course Credit
Theory :03
Practical :00
Tutorial :02
Credits :04
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Understand optimization techniques,
Classify the optimization problems,
Derive response quantities corresponding to design variable
Apply optimization techniques to trusses, beams and frames
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Introduction to optimization, optimization techniques for unconstrained and
constrained optimization problems 07
2. Classical Optimization, Lagrange
Multiplier technique and Kuhn –Tucker conditions 07
3. Solution of NLP by direct methods and by series of unconstrained optimization
problems, formulation of different types of structural optimization problem 07
Total 21
SECTION-II
4. Computation of derivatives of response quantities with respect to design
Variables. 08
5. Minimum weight design Of trusses, frame, etc. 08
6. Introduction Genetic Algorithm, Fussy Logics 05
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 16
Total 21
Term Work: Term work shall be based on the above mentioned course content.
Instructional method and Pedagogy:
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP etc.
2. Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an appreciation
for the concepts being taught in lectures.
Reference Books:
1. Optimization theory&application S.S.Rao
2. Structural optimization Majid
3. Advanced mathematics Kresysig
4. Numerical analysis Scarborough
5. Foundation Of structural optimization Marris
6. Optimum Structural Design Spun
7. Optimum Structural Design UriKrisch
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 17
Course Title Design of Bridges
Course Code SE208
Course Credit
Theory :03
Practical :00
Tutorial :02
Credits :04
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Achieve Knowledge of design and development of problem solving skills.
Explain the Bridge substructures and superstructures
Design and develop analytical skills.
Summarize the principles of design and detailing of bridges
Understands the different types of bridges.
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Introduction Historical Developments, Site Selection for Bridges, Classification of Bridges Forces on Bridges. Bridge substructures: Types of Loading as per IRC Design of Deck Slab for Class AA Loading Case , Design of Pipe Culverts
08
2. Box Culvert: Different Loading Cases IRC Class AA Tracked, Wheeled and Class A Loading, working out the worst combination of loading, Moment Distribution, Calculation of BM & SF, Structural Design of Slab Culvert, with Reinforcement Details
06
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 18
3. T Beam Bridge Slab Design: Proportioning of Components Analysis of interior Slab & Cantilever Slab Using IRC Class AA Tracked, Wheeled Class A Loading, Structural Design of Slab, with Reinforcement Detail. T Beam Bridge Cross Girder Design: Analysis of Cross Girder for Dead Load & Live Load Using IRC Class AA Tracked, Wheeled Class A Loading A Loads, Structural Design of Beam, with Reinforcement Detail.
07
Total 21
SECTION-II
4. T Beam Bridge Main Girder Design: Analysis of Main Girder for Dead Load & Live Load Using IRC Class AA Tracked, Wheeled Class A Loading Using COURBON’S Method, Analysis of Main Girder Using HENDRY-JAEGER and MORICELITTLE Method for IRC Class AA Tracked vehicle only, BM & SF for different loads, Structural Design of Main Girder With Reinforcement Details
11
5. PSC Bridges: Introduction to Pre and Post Tensioning, Proportioning of Components, Analysis and Structural Design of Slab, Analysis of Main Girder using COURBON’s Method for IRC Class AA tracked vehicle, Calculation of pre-stressing force, cable profile and calculation of stresses, Design of End block and detailing of main girder..
10
Total 21
Term Work: Term work shall be based on the above mentioned course content.
Instructional method and Pedagogy:
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP
etc.
2. Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an
appreciation for the concepts being taught in lectures.
Reference Books:
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 19
1. “Design of Bridges”- N Krishna Raju, Oxford & IBH Publishing Co New Delhi
2. “Principles and Practice of Bridge Engineering”- S P Bindra Dhanpat Rai & Sons
New Delhi
3. IRC 6 – 1966 “Standard Specifications And Code Of Practice For Road Bridges”-
Section II Loads and Stresses, The Indian Road Congress New Delhi
4. IRC 21 – 1966 “Standard Specifications And Code Of Practice For Road
Bridges”-Section III Cement Concrete (Plain and reinforced) The Indian Road
Congress New Delhi
5. IS 456 – 2000 “Indian Standard Plain and Reinforced Concrete Code of Practice”-
(Fourth Revision) BIS New Delhi
6. IS 1343 – “Indian Standard Prestressed Concrete Code of Practice”- BIS New
Delhi
7. Raina V.K., “Concrete Bridge Practice”- Tata McGraw Hill
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 20
Course Title Theory of Plates and Shells
Course Code SE209
Course Credit
Theory :03
Practical :00
Tutorial :02
Credits :04
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Achieve Knowledge of design and development of problem solving skills.
Understand the principles of Analysis and Design for curved surfaces
Design and develop analytical skills of plates and shells.
Summarize the performance of shells
Understand the concepts of energy principle.
Detailed Syllabus
Sr.
No. Name of chapter & details
Hours
Allotted
SECTION-I
1. Introduction
Introduction to plate theory, Small deflection of laterally loaded thin rectangular
plates for pure bending. Navier’s and Levy’s solution for various lateral loading
and boundary conditions (No derivation), Numerical examples
08
2. Energy Methods
Energy methods for rectangular and circular plates with clamped edges subjected
to symmetric loadings 06
3 Curved Surfaces
Introduction to curved surfaces and classification of shells, Membrane theory of
spherical shells, cylindrical shells, hyperbolic paraboloids, elliptic paraboloid and
conoids
07
Total 21
SECTION-II
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 21
4. Shells
Axially symmetric bending of shells of revolution, Closed cylindrical shells, water
tanks, spherical shells and Geckler’s approximation. Bending theory of doubly
curved shallow shells
08
5. Folded plates
Types- Structural Behavior of folded plates - Equation of three shears –
Application Whitney’s method of analysis 6
6. Design
Design and detailing of folded plates with numerical examples Design and
Detailing of simple shell problems – spherical domes, water tanks, barrel vaults and
hyperbolic paraboloid roofs.
07
Total 21
Term Work: Term work shall be based on the above mentioned course content.
Instructional method and Pedagogy:
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP
etc.
2. Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an
appreciation for the concepts being taught in lectures.
Reference Books:
1. Rudolph Szilard, Theory and Analysis of Plates, Prentice Hall, New Jercy 1986.
2. Timoshenko S.P and Woinowsky Krieger, Theory of Plates and Shells, McGraw Hill,
1984
3. G. S. Ramaswamy, ―Design and Construction of Concrete Shell Roofs‖, CBS
Publishers. 2005.
4. J N Reddy, Theory and Analysis of Elastic Plates and Shells, CRC Press, 2007.
5. K Chandra Shehara, Theory of Plates, University Press, Hyderabad, 2001.
SYLLABUS
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SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 22
Course Title Wind Effects on Structure
Course Code SE210
Course Credit
Theory :03
Practical :02
Tutorial :00
Credits :04
Course Learning Outcomes:
After Successful completion of the above course, students will be able to:
Achieve Knowledge of design and development of problem solving skills.
Understand the principles of strength and stability
Design and develop analytical skills.
Summarize the behavior of various structural systems.
Sr.
No.
Hours
Allotted
SECTION-I
1. Wind Characteristics
Variation of wind velocity, atmospheric circulations – pressure gradient force,
coriolis force, frictionless wind balance, geostrophic flow, boundary layer. Extra
ordinary winds – Foehn, Bora, Cyclones, Tornadoes etc
08
2. Static wind effects
Static wind effects and building codes with particular reference to IS 875 (Part-III),
wind speed map of India, introduction to the proposed revisions of IS 875 (Part III). 06
3. Dynamic wind effects
Wind induced vibrations, flow around bluff bodies, along wind and across wind
response, flutter, galloping, vortex shedding, locking, ovalling; analysis of dynamic
wind loads, codal provisions – gust factor, dynamic response factor; vibration
control and structural monitoring; exposure to perturbation method, averaging
techniques
07
Total 21
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2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 23
SECTION-II
4. Modeling
Modeling for approximate analysis, Accurate analysis and reduction techniques,
Analysis of buildings as total structural system considering overall integrity and
major subsystem interaction, Analysis for member forces, drift and twist -
Computerized three dimensional analysis – Assumptions in 3D analysis –
Simplified 2D analysis
08
5. Structural elements
Sectional shapes, properties and resisting capacity, design, deflection, cracking,
prestressing, shear flow, Design for differential movement, creep and shrinkage
effects, temperature effects and fire resistance
10
6. Stability of tall buildings
Overall buckling analysis of frames- P- Delta analysis- Translational,
torsional instability, out of plumb effects, effect of foundation rotation 03
Total 21
Term Work: Term work shall be based on the above mentioned course content.
Instructional method and Pedagogy:
1. Lectures will be conducted with the aid of multi-media projector, black board, OHP etc.
2. Assignments based on course content will be given to the students at the end of each
unit/topic and will be evaluated at regular interval.
3. Surprise tests/Quizzes/Seminar/Tutorials will be conducted.
4. The course includes tutorials, where students have an opportunity to build an appreciation
for the concepts being taught in lectures.
Reference Books:
SYLLABUS
2018-19 M.TECH 2ND
SEM STRUCTURAL ENGINEERING (2018-20 BATCH) Page 24
1. Dynamics of Structures‖, McGraw Hill, Kogokusha
2. Mario Paz, ―Structural Dynamics-Theory and computaitons‖, 2/e/1999, CBS Publishers.
3. MukhopadhyayMandhujit, ―Vibrations, Dynamics and Structural Systems‖, Oxford and
IBH, 1/e/2000
4. Chopra Anil K., ―Dynamics of Structures- Theory and Applications to Earthquake
Engg.‖, Prentice Hall, India, 2/e/2002
5. Pankaj Agrawal, Manish Shrikhande, Earthquake Resistant Design of Structures,
Prentice-Hall of India.
6. IS Codes : IS:1893, IS:4326, IS:13920, IS:13828, IS:456 ,IS875 Part III
7. Earthquake Resistant Design of Building Structures, Vinod Hosur, WILEY (India)
8. Earthquake Resistant Design of Structures, Duggal, Oxford University Press 4.
Earthquake resistant design of structures - Pankaj Agarwal, Manish Shrikande - PHI India