ADAMAS UNIVERSITY

Course Curriculum for 1st Year Undergraduate (B.Tech) Program in

School of Engineering & Technology

ADAMAS UNIVERSITY

SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: 1st Year B.Tech All Branches

SEMESTER I

S. No Type Course code Course Title L T P Contact

Hrs/wk Credits

1 Theory SMA41101 Mathematics-I 3 1 0 4 4.0

2 Theory SPH41109 Physics – I 3 0 0 3 3.0

3 Theory ECS41101 Programming and Data

Structure 3 0 0 3 3.0

4 Theory HEN41117 HSS –I 3 0 0 3 3.0

5 Theory HEN41119 HSS –II 3 0 0 3 3.0

6 Practical SPH41209 Physics – I Lab 0 0 3 3 2.0

7 Practical ECS41201 Data Structure Lab 0 0 3 3 2.0

8 Practical ECE41201 Engineering Drawing and

CAD 1 0 3 4 3.0

Total 16 1 9 26 23

ADAMAS UNIVERSITY

SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: 1st Year B.Tech All Branches

SEMESTER II

S. No Type Course code Course Title L T P Contact

Hrs/wk Credits

1 Theory SMA41102 Mathematics– II 3 1 0 4 4.0

2 Theory SPH41108 Physics - II 3 0 0 3 3.0

3 Theory SCY41106 Chemistry 3 0 0 3 3.0

4 Theory EEE41102 Electrical Technology 3 0 0 3 3.0

5 Theory SBT41108 Life Sciences 3 0 0 3 3.0

6 Theory EME41104 Engineering Mechanics 3 0 0 3 3.0

7 Practical SCY41206 Chemistry Lab 0 0 3 3 2.0

8 Practical EEE41202 Electrical Technology Lab 0 0 3 3 2.0

9 Practical EME41204 Engineering Workshop 0 0 3 3 2.0

Total 18 1 9 28 25

Total Credit (Second Year): 48

ADAMAS UNIVERSITY SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: B. Tech in Civil Engineering SEMESTER III

S. No

Type Course code

Course Title L T P Contact Hrs/wk

Credits

1. Theory SMA42101 Transform Calculus 3 1 0 4 4

2. Theory ECE42101 Fluid Mechanics & Hydraulics 3 0 0 3 3

3. Theory EME42103 Solid Mechanics 3 0 0 3 3

4. Theory ECE42105 Surveying-I 3 0 0 3 3

5. Theory HEN42111 HSS-III 3 0 0 3 3

6. Compulsory

Theory ECE42107

Non Credit Course –III ( Introduction to Civil

Engineering) 3 0 0

3

0

7. Practical ECE42201 Fluid Mechanics Lab 0 0 3 3 2

8. Practical ECE42203 Solid Mechanics Lab -I 0 0 3 3 2

9. Practical ECE42205 Surveying Practice 0 0 3 3 2

TOTAL 18 1 9 29 22

ADAMAS UNIVERSITY SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: B. Tech in Civil Engineering SEMESTER - IV

SL. No

Type Course code

Course Title L T P Contact Hrs/wk

Credits

1. Theory SMA42102 Numerical Techniques 3 1 0 4 4

2. Theory ECE42102 Structural Analysis -I 3 1 0 4 4

3. Theory ECE42104 Civil Engineering Materials 3 0 0 3 3

4. Theory ECE42106 Soil Mechanics -I 3 0 0 4 4

5. Theory ECE42108 Surveying - I 3 0 0 3 3

6. Practical ECE42102 Estimation & Valuation 0 0 3 3 2

7. Practical ECE42104 Soil Mechanics - II 0 0 3 3 2

8. Practical ECE42106 Civil Engineering Materials Lab 0 0 3 3 2

9. Sessional ECE42108 Surveying practice 0 0 3 3 2

TOTAL 15 3 12 30 26

Total Credit (Second Year): 53

ADAMAS UNIVERSITY SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: B. Tech in Civil Engineering SEMESTER V

S. No

Type Course code

Course Title L T P Contact Hrs/wk

Credits

1. Theory ECE43101 Design of RC Structure-I 3 1 0 4 4

2. Theory ECE43103 Structural Analysis -II 3 1 0 4 4

3. Theory ECE43105 Soil Mechanics-II 3 0 0 3 3

4. Theory ECE43107 Transportation Engineering -I 3 0 0 3 3

5. Theory HEC43181 HSS –IV 3 0 0 3 3

6. Practical ECE43201 Soil Mechanics Lab –II 0 0 3 3 2

7. Practical ECE43203

Transportation Engineering Lab-I

0 0 3 3

2

8. Practical ECE43205 CAD 0 0 3 3 2

9. Sessional ECE43207 Detailing of RC Structure 0 0 3 3 2

TOTAL 15 2 12 29 25

ADAMAS UNIVERSITY SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: B. Tech in Civil Engineering SEMESTER VI

S. No

Type Course code

Course Title L T P Contact Hrs/wk

Credits

1. Theory ECE43102 Design of Steel Structure 3 1 0 4 4

2. Theory ECE43104 Structural Analysis -III 3 1 0 4 4

3. Theory ECE43106 Water Resources Engineering -I 3 0 0 3 3

4. Theory ECE43108 Transportation Engineering - II 3 0 0 3 3

5. Theory ECE43110 Engineering Geology 3 0 0 3 3

6. Practical

ECE43202 Transportation Engineering Lab-

II 0 0 3

3 2

7. Practical ECE43204 Engineering Geology Lab 0 0 3 3 2

8. Sessional ECE43206 Detailing of Steel Structure 0 0 3 3 2

9. ECE43302 Seminar 0 0 3 3 2

TOTAL 15 2 12 29 28

Elective –I

1. Pre-stressed Concrete.

2. Design of Bridge Structure.

3. Waste Management.

ADAMAS UNIVERSITY SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: B. Tech in Civil Engineering TRI-SEMESTER VII

S. No

Type Course code

Course Title L T P Contact Hrs/wk

Credits

1. Theory ECE44101 Environmental Engineering-I 3 0 0 3 3

2. Theory ECE44103 Water Resources Engineering-II 3 0 0 3 3

3. Theory ECE44105 HSS-V 3 0 0 3 3

4. Theory ECE44107 Management 3 0 0 3 3

5. Theory ECE44109 Elective-I 3 0 0 3 3

6. Practical ECE44201 Environmental Engineering Lab 0 0 3 3 2

7. Sessional ECE44401 Project - I 0 0 3 3 2

8. ECE44601 Internship/Vocational Training 0 0 0 0 2

TOTAL 15 0 6 21 21

ADAMAS UNIVERSITY SCHOOL OF ENGINEERING & TECHNOLOGY

UG PROGRAM: B. Tech in Civil Engineering SEMESTER -VIII

S. No

Type Course code

Course Title L T P Contact Hrs/wk

Credits

1. Theory ECE44102 Environmental Engineering -II 3 0 0 3 3

2. Theory ECE44104 Hydraulics Structure 3 0 0 3 3

3. Theory ECE44106 Elective –II 3 0 0 3 3

Theory ECE44108 Elective –III 3 0 0 3 3

4. Theory

ECE44110 Construction Planning and

Management 3 0 0 3 3

5. Sessional ECE44402 Project-II 0 0 3 3 2

6. Sessional ECE44302 Seminar 0 0 3 2 2

7. ECE44502 Grand Viva 0 0 0 0 2

TOTAL 15 0 6 20 21

Elective –II Elective –III

1. Earthquake Engineering. 1. Advance RC design

2. Design of Tall building. 2. Elasticity and Plasticity.

3. Foundation Engineering. 3. Composite Structure.

4. Advance Structural Analysis.

Total Credit (Forth Year): 42

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – I

Module 1: Differential Calculus: Successive differentiation, Leibnitz’s Theorem,

Rolle’s theorem, Mean value theorems, Taylor’s and Maclaurin’s theorems with remainders,

Expansions, indeterminate forms, infinite Series, curve tracing, functions of several variables, partial

Differentiation, total differentiation, Euler’s theorem and generalization, maxima and minima of

functions of several variables (two and three variables), Lagrange’s method of multipliers, change of

variables, Jacobean’s, asymptote, curvature.

Module 2: Ordinary differential equations of first order: Formation of differential equations;

Separable equations; equations reducible to separable form; exact equations, integrating

factors, linear first order equations; Bernoulli’s equation; Orthogonal trajectories.

Module 3: Ordinary linear differential equations of higher order: Homogeneous linear equations of arbitrary order with constant coefficients, Non-

homogeneous linear equations with constant coefficients, Euler and Cauchy’s equations, Method of

variation of parameters, System of linear differential equations., modelling of electrical circuit.

Module4: Series solution of differential equation, power series method, Legendre’s equation and

Legendre’s polynomials, Bessel’s equation, Bessels function and its application.

Mathematics -I SMA41101 3-1-0 4 Credits

Text Books:

1 Erwyn Kreyszig : Advanced Engineering Mathematics, John Wiley and Sons

2 Higher Engineering Mathematics by B.V. Ramana, Tata McGraw-Hill.

3 B.S.Grewal : Higher Engineering Mathematics, Khanna Publications

4 C B Gupta, S R Singh, Mukesh Kumar: Engineering Mathematics, Mc Graw Hill Publication.

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – I

Module 1: Vector Analysis Axial and polar vectors, dot product and cross product, scalar triple product and vector triple product.

Scalar and vector fields --- gradient, divergence and curl, statement of divergence theorem,

statement of Stokes' theorem.

Module 2: Mechanics of a Particle

(a) Newton's laws of motion, principle of conservation of linear momentum, time and

path integral of force, conservative force field, concept of potential, conservation of

total energy, equation of motion of a system with variable mass.

(b) Rotational motion, angular velocity, angular acceleration, angular momentum,

torque, fundamental equation of rotational motion, principle of conservation of angular

momentum, radial and cross-radial acceleration.

Module 3: Dynamics of Rigid Bodies Moment of inertia and radius of gyration - their physical significance, theorems of

parallel and perpendicular axes, rotational kinetic energy, calculation of moment of

inertia for some simple symmetric systems. Physical significance of MI.

Module 4: Gravitation

Gravitational potential and intensity due to thin uniform spherical shell and solid

sphere of uniform density, escape velocity.

Module 5: Elasticity

Elastic moduli and their interrelations, torsion of a cylinder, bending moment,

cantilever, simply supported beam with concentrated load at the center, strain energy.

Module 6: Viscosity

Streamline and turbulent motion, Poiseuille's formula, critical velocity, Reynolds

number, Bernoulli's theorem, Stokes' law (statement only).

Module7: Surface Tension

Surface tension and surface energy, molecular theory, angle of contact, elevation and

depression of liquid columns in a capillary tube, excess pressure in a spherical bubble and

Physics-I SPH41109 3-0-0 3 Credits

spherical drop.

Module8: Simple Harmonic Motion

Differential equation and its solution, analytical treatment, Lissajous figures, natural,

damped and forced vibration, resonance, sharpness of resonance.

Module9: Kinetic Theory of Gases

Perfect gas, pressure exerted by it, Maxwell's law of distribution of molecular

velocities (statement only) - r.m.s, mean and most probable velocities, degrees of freedom,

principle of equipartition of energy - application in simple cases. Equation of state - defects

of ideal gas equation, van der Waals equation (qualitative study), and critical constants.

Module10: Thermodynamics

Basic concepts (equilibrium state, state function, exact and inexact differential),

internal energy as state function. First law of thermodynamics and its application. Isothermal

and adiabatic changes and their relations, indicator diagrams. Reversible and irreversible

processes, second law of thermodynamics, Carnot cycle and its efficiency, entropy and its

physical interpretation.

Module11: Thermal Conductivity

Steady state and variable state, thermal and thermometric conductivity, Fourier

equation for one-dimensional heat flow and its solution, cylindrical flow of heat.

Module12: Radiation

Nature of radiant heat, emissive and absorptive power, Kirchhoff's law, black body

radiation, Stefan's law, Newton's law of cooling, Planck's distribution law (only statement),

Wien's displacement law.

Module 13: Physical Optics

Light as an electromagnetic wave, full electromagnetic spectrum, properties of

electromagnetic waves, Huygens' principle, Interference of light, Young's experiment,

intensity distribution, conditions of interference, Diffraction of light, Fresnel and

Fraunhofer class, Fresnel's half-period zones, zone plate. Fraunhofer diffraction due to a

single slit and plane transmission grating (elementary theory). Polarization of light Different

states of polarization, Brewster's law.

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – I

Module 1: Basics of C Programming :Characters used in C, Identifiers, Keywords, Data type & sizes,

Constants &Variables, Various Operators used such as Arithmetic Operators, Relational & Logical

Operators, Increment & Decrement Operators, Assignment Operators, Conditional or Ternary

Operators, Bitwise Operators & Expressions; Standard Input & Output, formatted input scanf( ),

formatted output printf( ); Flow of Control, if-else, switch-case, Loop Control Statements, for loop,

while loop, do-while loop, nested loop, break, continue, goto, label and exit( ) function

Module 2: Functions and Pointers: Definition of Function, Declaration or Prototype of Function, Various

types of Functions, Call by Value, Call by Reference, Recursion, Tail Recursion, Definition of

Pointer, Declaration of Pointer, Operators used in Pointer, Pointer Arithmetic, Functions with Pointer

Module 3: Introduction to Data Structures: Basic Terminology, Elementary Data Organization, Algorithm,

Efficiency of an Algorithm, Time and Space Complexity, Asymptotic notations: Big-Oh, Time-Space

trade-off. Abstract Data Types (ADT)

Programming and Data

Structure ECS41101 3-0-0 3 Credits

Arrays and String: Definition, Single and Multidimensional Arrays, Representation of Arrays -

Row Major Order, and Column Major Order, Application of arrays – searching and sorting, Sparse

Matrices and their representations. Definition of a String, Declaration of a String, Initialization of a

String, Various String Handling Functions with example

Structures and Unions: Definition of a Structure, Declaration of a Structure & Structure Variable,

Initialization of a Structure, Operators used in Structure, Structure within Structures, Union,

Difference between a Structure and an Union

Files: Types of File, File Processing, Handling Characters, Handling Integers, Random File

Accessing, Errors During File Processing

Module 4: Stacks and Queues: ADT Stack, Array Implementation Multiple Stacks, Applications of Stacks –

Conversion from Infix to Postfix, Evaluation of Postfix Expressions, Prefix Notation, etc. ADT

queue, Linear Queue, Circular Queue, Priority Queue, Array Implementations of Queues,

Applications of Queues Operations on Queue: Create, Add, Delete, Full and Empty, Circular queues,

Array and linked implementation of queues in C, Dequeue and Priority Queue.

Module 5: Linked lists: Array Implementation and Dynamic Implementation of Singly Linked Lists, Doubly

Linked List, Circularly Linked List, Operations on a Linked List. Insertion, Deletion, Traversal,

Polynomial Representation and Addition, Generalized Linked List.

Trees: Basic terminology, Binary Trees, Binary Tree Representation: Array Representation and

Dynamic Representation, Complete Binary Tree, Algebraic Expressions, Extended Binary Trees,

Array and Linked Representation of Binary trees, Tree Traversal algorithms: Inorder, Pre-order and

Postorder, Threaded Binary trees, Traversing Threaded Binary trees, Huffman algorithm.

Module 6:

Graphs: Terminology, Sequential and linked Representations of Graphs: Adjacency Matrices,

Adjacency List, Adjacency Multi list, Graph Traversal : Depth First Search and Breadth First Search,

Connected Component, Spanning Trees, Minimum Cost Spanning Trees: Prims and Kruskal

algorithm. Transistive Closure and Shortest Path algorithm: Warshal Algorithm and Dijikstra

Algorithm, Introduction to Activity Networks.

Text Books:

1 ―The Complete Reference‖, 4th Edition by Herbert Schildt, Tata Mcgraw Hill Education

2 ―Data Structures Using C‖, 7th Edition by Aaron M. Tenenbaum, Yedidyah Langsam and Moshe

J. Augenstein, PHI Learning Private Limited, Delhi India

Reference Books:

1 ―The C Programming Language‖, 2nd

Edition, Brian W. Kernighan, Dennis M. Ritchie, PHI

2 ―Schaum's Outline of Programming with C‖, 2nd

Edition, Byron S. Gottfried, Mcgraw Hill

Education

3 ―Data Structures and Program Design in C‖, 2nd

Edition by Robert Kruse, C. L. Tondo, Bruce

Leung, Shashi Mogalla, Pearson Education

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – I

For the subject HSS-I (HEN41117) students have to choose from anyone of the offered courses

Level 2 A

Unit-I: Oral Skill I

Interactions in different situations- Formal dialogues- Group interactions

Unit-II: Oral Skill II

Inviting people to a programme- Apologizing and responding to apologies- Congratulations and

response-Showing appreciation- Expressing sympathy, regret or consolation-Asking for, granting

and refusing permission

Unit-III: Oral Skill III

Debates and Extempore

Unit-IV: Reading Skill

Newspaper Reading and Interpretation

Unit-V (Writing Skill I)

Importance of writing skills – Effective means of written communication –Report Writing –

Memo writing – Summary writing

Unit-VI (Writing Skill II)

Article, Paragraph, Applications, Emails and Drafts

Suggested Reading:

1. Spoken and Written Communication. Board of Editors. Orient Blackswan.

2. M. S Gupta. Current English Grammar and Usage. Prentice Hall India Learning Private

Limited; 2016.

3. P. C. Das. Spoken English and Functional Grammar.

Level 2 B

Unit-I

Short Stories— Sherlock Holmes: ―The Speckled Band‖

Unit-II

Poetry— Wilfred Owen: ―Strange Meeting‖; W H Auden: ―The Unknown Citizen‖

Unit-III

Drama— William Shakespeare: As You Like It

Unit-IV

Newspaper Reading and Interpretation

Unit-V (Writing Skill I)

Importance of writing skills – Effective means of written communication – Letter Writing –

Report Writing – Memo writing – Summary writing

Unit-VI (Writing Skill II)

Article, Paragraph, Report, Applications, Emails and Drafts

Suggested Reading:

1. Sir Arthur Conan Doyle: Sherlock Holmes and the Adventure of the Speckled Band. Lerner

Books.

2. W. H. Auden: Collected Poems, Vintage International.

3. The Poems of Wilfred Owen. Wordsworth Poetry Library

4. Spoken and Written Communication. Board of Editors. Orient Blackswan.

5. M. S Gupta. Current English Grammar and Usage. Prentice Hall India Learning Private

Limited; 2016.

6. William Shakespeare: As You Like It. Arden Edition

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – I

Module 1: An attempt to define and identify the contours of Ethics and its relation with Religion,

Aesthetics and Professional Education Human Values including basic five human values (against Satya

(Truth), Dharam (Righteous conduct), Prem (Love), Shanti (Peace), Ahinsa (Non-violence), Ethics &

Morality in Law, General-Lectures by distinguished persons on this subject on regular basis.

Fundamental Duties of citizen. Basic values of the Constitution: Democracy, Republicanism, Rule of law,

Constitutionalism and Respect for Minority Rights.

Module 2: Human Rights – Jurisprudence of human rights nature and definition, Universal protection of

human rights, Regional protection of human rights, National level protection of human rights, Human

Rights and vulnerable groups.

Module 3: Theory and Nature of Political Institutions

Concept of State / Nation

Organs of Government – Legislative, Executive and Judiciary

PROFESSIONAL ETHICS, FUNDAMENTAL

DUTIES AND LEGAL STUDIES (HSS – II) HEN41119 3-1-0 3credits

Separation of Powers – Parliamentary Sovereignty and Judicial Independence

Constitutional Framework of India.

Module 4: Nature and Sources of Law

Legislation – Process, delegated and subordinate legislation

Case law- Stare decises, precedents within the hierarchy of courts

Authoritative Sources, Custom, Law reform

Module 5: Historical Evolution of Indian Legal System

Ancient Indian Law, English Law in India

Administration of Justice in British India

Charter of 1861 and subsequent Charters

Establishment of High Courts and the Federal Courts

Drafting of the Indian Constitution

Ancient Indian Law in Modern Legal Framework

Module 6: Civil and Criminal Courts And Process

The Civil Court Structure, The Criminal Court Structure

The Civil Process, The Criminal process- Investigation and Prosecution

Module 7: Miscellaneous Laws

Growing importance of intellectual property rights and related laws in India

Industrial relations laws

An overview of the Law of Contract

Human resource and related laws

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – II

Module 1: Linear Algebra: Elementary row and column operations on a matrix; Rank of matrix ,

Normal form, Inverse of a matrix using elementary operations, Consistency and solutions of systems

of linear equations using elementary operations, Gauss Elimination method. Caley-

Hamillton theorem, eigen values and eigen vectors, Symmetric and skew-symmetric matrices,

orthogonal matrices, complex matrices, Hermitian and skew-Hermitian matrices, unitary matrices

and similarity of matrices. Unitary matrix, Normal matrix, Algebraic and geometric multiplicity,

Diagonalization, spectral theorem for Real symmetric matrices, Application of quadratic forms.

Module 2: Vector space and Linear transformations: Definition of vector space, subspaces, linear

combination, Linearly dependent and linearly independent vectors, Basis of vector space, Dimension,

Rank-Nullity theorem (statement and verification by examples), Definition of linear transformation,

types of linear transformations (Rotation, Reflection, Expansion, Contraction, Projection), Matrix of

Linear transformations, Change of basis and similarity.

Mathematics -II SMA41102 3-1-0 4 Credits

Module 3: Functions Of Complex Variables: Reorientation, Analytic function, Cauchy – Riemann

equation (Cartesian and Polar forms), Harmonic functions, conformal mappings, complex

integration, Cauchy’s theorem and integral formula, Singularities, Taylor’s and Laurent’s Series

theorem, evaluation of integrals using residues.

Module4: Partial Differential Equation: Introduction, classification, construction and geometrical

interpretation of first order partial differential equations (PDE), method of characteristic and general

solution of first order PDE, canonical form of first order PDE, equations solvable by direct

integration, Langrange’s method, solution of non-linear first order partial differential equation by

Charpit’s method, special types of first order PDE, solution satisfying given conditions, Jacobi’s

method.

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – II

Module 1. Electrostatics

Quantization of charge, Coulomb's law, field intensity and potential, example of point

charge, Gauss' theorem, simple applications, potential and field due to an electric dipole,

mechanical force on the surface of a charged conductor. Dielectric medium, polarization,

electric displacement. Capacitor, Parallel-plates and cylindrical, energy stored in parallel

plate capacitor.

Text Books:

1 Erwyn Kreyszig : Advanced Engineering Mathematics, John Wiley and Sons

2 Higher Engineering Mathematics by B.V. Ramana, Tata McGraw-Hill.

3 David C. Lay, Linear algebra and its application, (Latest edition), Pearson publication, New Delhi.

4 E. Kreyszig, Advanced engineering mathematics (Latest edition), John Wiley.

5 H. Anton, Elementary linear algebra with applications (Latest edition), John Wiley. 6 Erwyn Kreyszig : Advanced Engineering Mathematics, John Wiley and Sons

Physics-II SPH41108 3-0-0 3 Credits

Module 2. Steady Current

Network analysis: Kirchhoff’s laws, Thevenin and Norton's theorem, Wheatstone

bridge, potentiometer.

Module 3. Thermoelectricity

Seebeck, Peltier, and Thomson effects, laws of thermoelectricity, thermoelectric curve ---

neutral and inversion temperature, thermoelectric power.

Module 4. Magnetic effect of current

Biot-Savart law, Ampere's circuital law (statement only), magnetic field due to a straight

conductor, circular coil, solenoid, endless solenoid, Magnetic field due to a small current

loop, concept of magnetic dipole, introduction magnetic scalar and vector potential.

Module 5. Lorentz force

Force on a moving charge in simultaneous electric and magnetic fields, Cyclotron motion

and Cycloid motion (basic discussion only) force on a current carrying conductor in a

magnetic field.

Module 6. Magnetic materials

Intensity of magnetization, relation between B, H and M. Bar magnet, Magnetic field due to

a bar magnet (end on and broad side on positions), magnetic susceptibility, dia, para and

ferromagnetic materials, statement of Curie's law. Hysteresis in a ferromagnetic material,

hysteresis loss.

Module 7. Electromagnetic induction

Faraday’s law of induction, Lenz’s law, self and mutual inductances in simple cases,

energy stored in inductance.

Module 8. Transient currents

growth and decay of currents in L-R circuit; charging and discharging of capacitor in C-R

circuit.

Module 9. Alternating current

Mean and r.m.s. values of current and e.m.f with sinusoidal wave form; LR, CR and series

LCR circuits, reactance, impedance, phase-angle, power dissipation in AC circuit, power

factor, vector diagram, resonance in a series LCR circuit, Q-factor, principle of ideal

transformer.

Module 10. Diodes and Transistors

P-N junction diode, bridge rectifier, capacitance input filter, Zener diode, voltage

regulator, Transistors --- α and β and their interrelations; output characteristics in CE mode,

single stage CE amplifier --- approximate expressions of current and voltage gain

with the help of 'Load Line'.

Module 11. Digital Electronics

binary systems, binary numbers. Decimal to binary and reverse conversions, binary addition

and subtraction. Logic gates: OR, AND, NOT gates --- truth tables. Statement of de

Morgan's theorem, NOR and NAND universal gates.

Module 12. Special Theory of Relativity

Postulates of STR, formulae of (i) Length contraction; (ii) Time dilation; (iii) Velocity

addition; (iv) Mass variation, and (v) Mass-energy equivalence.

Module 13. Elementary quantum Physics

Planck's concept of blackbody radiation and radiation formula (statement only), qualitative

discussion of photo-electric effect and Compton effect in support of quantum theory, Raman

effect. Wave nature of material particles, wave-particle duality, wavelength of de Broglie

waves, Heisenberg uncertainty principle, and Schrödinger equation, particle in a one-

dimensional infinite well, energy eigenvalues, wave function and its probabilistic

interpretation. Bohr's theory of hydrogen spectra, concept of quantum number, Pauli

Exclusion Principle.

Module 14. Laser:

Principle of Laser action, Population Inversion, Einstein’s A and B coefficients, feedback of

energy in a resonator,3 level and 4 level systems, Helium-Neon and Semiconductor Lasers.

Application of Laser.

Module 15. Fibre Optics:

Optical fibre, core and cladding, total internal reflection, optical fibre as waveguide, step

index and graded index fibre, communication through optical fibres, energy loss, band width

and channel capacity for a typical system, attenuation and dispersion, splicing and couplers,

Fibre optic sensors.

Module 16. Superconductor :

Definition, Type I, Type II, Meissner effect, Josephson effect

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – II

Module 1: Thermodynamics: Thermodynamics of Chemical Processes: Review of 1

stlaw, Concept of entropy,

Chemical potential, Equilibrium conditions for closed systems, Phase and reaction equilibria,

Maxwell relations.

Module 2: Reaction Dynamics, Catalysis & Electrochemistry: Rate laws, 1

stOrder reaction & 2

ndorder

reaction, Arrhenius equation,Mechanism and Theories of reaction rates,Characteristics and Types of

Catalyst, Theories of Catalysis, Electrode potential, Redox reaction & Nernst Equation.

Module 3: Solid State and Molecular spectroscopy:.Homonuclear and Heteronuclear concepts, Non –

covalent interaction, Van der waals bonding, hydrogen bonding, Idea of spatial periodicity of lattice,

Unit cells, Bravias lattice, Atomic packing factor of SCC, BCC and FCC, Band theory, Conductors

Semiconductors and insulators. Basic concepts of spectroscopy, selection rule, fundamentals of IR,

UV-Vis, NMR spectroscopy

Module 4: Co-Ordination Chemistry:Transition elements, Warner’s co-ordination theory, Structure of Co-

ordination Compounds corresponding to Co-ordination number 2 to 6, Types of ligands, Isomerism

& its types viz. Geometrical, Optical, Ionization, linkage & Co-ordination isomerism, Theories of

bonding in Co-ordination compounds viz. crystal field theory and valance bond theory.

Module 5: Reactivity of Organic Molecules, Types of Reactions and Stereochemistry: Inductive effect,

Resonance, Hyper conjugation, Electromeric effect, Carbocation, carbanion & free radicals,

Substitution reactions, Elimination reactions, Addition reactions, & their Mechanisms. Introduction

to stereochemistry, stereochemical nomenclature & terminology (chiral carbons, allenes, biphenyls,

etc.) and nomenclature (R/S, E/Z, D/L, d/l). Identification of stereo chemical relationship

(enantiomers, diastereomers, epimers, etc.).

Chemistry SCY41106 3-0-0 3 Credits

Module 6:

Polymers& Fuel Chemistry:Polymerization, Mechanism of Addition polymerization, Classification

of plastics, Preparation properties & industrial applications of PTFE, PVC, Phenolic resin &

Polyester resin, Conducting polymers & Biopolymers. Solid Fuel: Coal, Classification of coal, Coal

analysis. Liquid fuel: Petroleum, classification of petroleum, Thermal cracking, Octane number,

Cetane number, Aviation Fuel Bio-diesel. Gaseous fuels: Natural gas, water gas, bio gas.

Text Books:

1 P. W. Atkins, Physical Chemistry, ELBS/Oxford, 7th Edition, 1995

2 G.W.Castellan, Physical Chemistry

3 D. A. McQuarrie and J.D. Simon, Physical Chemistry - a molecular approach, Viva Books Pvt.

Ltd. (1998)

4 P. C. Rakshit, Physical Chemistry, Sarat Book House (7thEdition)

5 Cotton, F A,Wikinson G. and Gaus, P L,Basic Inorganic Chemistry

6 J. D. Lee, Concise Inorganic Chemistry, 4th Edition, ELBS, 1991

7 I.L. Finar,Organic Chemistry,Vol – I & II, Pearson Education

8 Morrison & Boyd, Organic Chemistry

9 P. Sykes, Mechanism in Organic Chemistry, Orient Longman

10 Joel R. Fried, Polymer Science and Technology, Pearson Education (2nd

Edition)

11 S. Sarkar, Fuels and Combustion, Taylor & Francis (3rd

Edition), 2009

12 Kuriacose& Raja Ram ,Chemistry in Engineering and Technology, Vol.1 & 2 by, Tata McGraw

Hill & Co

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – II

Module 1: Introduction to Electrical Engineering

Sources of energy; General structure of electrical power systems; Steam power generation; Hydel

power generation; Gas and Nuclear power generation; Power Transmission and Distribution;

overhead lines; underground cables; Transformers; Basic Principle and operation

Module 2: DC Networks

Kirchoff’s laws; node voltage method; mesh current method; Delta-star and star-delta conversion;

Network theorems; Superposition principle; Thevenin’s theorem; Norton’s theorem

Module 3: AC Circuits

Definitions: average and effective values of Sinusoids; Solution of R,L,C series circuits;

Significance of j operator; complex representation of impedances; Phasor diagram; power factor,

power in complex notation; solution of parallel and series – parallel Circuits; Three phase EMF

generation; delta and Y – connections; line and phase quantities

Module 4: Basics of Semi-Conductors and PN Junction

Introduction; Carrier Concentrations- the Fermi Level; Electron and Hole Concentration at

Equilibrium; Temperature Dependence of Carrier Concentration; Drift and diffusion current; The

Hall Effect; Optical Absorption, Luminescence; PN Junction Diode in Equilibrium Conditions; PN

Junction Diode in Forward Biased and Reverse Biased Condition; Breakdown in PN Junction

Electrical Technology EEE41102 3-0-0 3 Credits

Diodes.

Module 5: Bipolar Junction Transistors

Introduction, Types: NPN and PNP; Current Components; Early Effect Ebber’s Moll Model;

Different Configurations of a Transistor and its Characteristics; Transistor as an Amplifier (CE, CB,

CC); Transistor as a Switch

Module 6: Field Effect Transistors

Introduction; JFET and MOSFET; Realization of digital logic circuit using MOSFET (AND, OR,

NOT etc.); Realization of switching circuits using MOSFET

Module 7: Electronics Instruments & Digital Electronics Fundamental:

Signal generator, Mustimeter, operation of CRO and its application. Number systems, Conversions and codes,

Logic gates and truth tables.

Text Books:

1 Basic Electrical Engineering-Abhijit Chakrabarti, SudipNath, Chandan Kumar Chnada, Tata

McGraw-Hill publishing Limited, New Delhi

2 Principles of Electrical Engineering and Electronics- V K Mehta, Rohit Mehta , S Chand and

Company , New Delhi

3 Solid State Electronic Devices- Ben G. Streetman and Sanjay Kumar Banerjee, PHI.

Reference Books:

1 Basic Electrical Engineering-D P Kothari, I J Nagrath, Tata Mcgraw-Hill Publishing Company,

New Delhi

2 Integrated Electronics: Analog & Digital Circuit Systems – Jacob Millman & Halkias, TMH 3 Digital Principles & Applications, 8th Edition by Donald P Leach, Albert Paul Malvino, Goutam

Saha (Tata Mcgraw Hill Publishing Co Ltd, 2014)

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – II

Module 1: BASIC CELL BIOLOGY

Introduction; Living Organisms; Cells and Cell theory, Cell Structure and Function, Genetic

information, protein synthesis, and protein structure, Cell metabolism; Cell growth, reproduction,

and differentiation; Cell division, cell cycle and apoptosis; ATP synthesis and Glycolysis;

Respiration and photosynthesis.

Module 2: BIOCHEMISTRY AND TRANSPORT PROCESS

Chemistry of life: chemical bonds; Non-covalent interactions and free energy changes in biological

processes; Fundamentals of momentum, heat and mass transport as applied to biological systems;

Human body as a thermodynamic system; Blood Rheology, Fluid mechanical aspects of some

diseases and organs; Biochemistry and Human biology; Stem cells and Tissue engineering.

Life Sciences SBT41108 3-0-0 3 Credits

Module 3: CHEMICAL BIOLOGY

Carbohydrates; Lipids; Proteins: structure and sequencing; DNA: structure and sequence, replication,

recombination; RNA synthesis; Genetic code and protein biosynthesis; Recombinant DNA

technology.

Module 4: ENZYMES AND INDUSTRIAL APPLICATIONS

Enzymes: mechanism, kinetics and inhibition; Biological catalysts, Proteases, Carbonic anhydrase,

Restriction enzymes, and Nucleoside monophosphate kinases.

Module 5: FERMENTATION TECHNOLOGY AND APPLICATIONS

Introduction and scope of microbial processes. Sources of industrial cultures and maintenance.

Alcoholic fermentation: Production of Industrial Alcohol. Brewing and malting, manufacture of wine

and other distilled liquors. Microbial Foods – Food, Fodder and Baker's yeast, applications of the

nonconventional raw materials; Nutritional characteristics of food yeast, mushroom production;

Vitamins- Vitamin B-2, Riboflavin, Soya-sauce & cheese production. Production of acids, viz., citric,

lactic and gluconic acid. Mechanism of each fermentation, their uses. Production of Amino acids and

Antibiotics and its new Developments. Production of Organic Acids its spoilage and prevention.

Module 6: MECHANOCHEMISTRY

Molecular Machines/Motors; Cytoskeleton; Biosensors; Bio-Micro devices.

Module 7: HUMAN PHYSIOLOGY

Physiology of cells and molecules; cellular physiology of the nervous system; cardiovascular and

respiratory systems; gastrointestinal and renal systems; endocrine and reproductive systems.

Module 8: IMMUNE SYSTEM AND CELL SIGNALING

Immune system; General principles of cell signaling.

Module 8: IMPACT OF BIOLOGY ON SOCIETY AND MANKIND

Crop management, Disease control, Biological Hazards and safety; Unsolved Problems in Biology.

Text Book:

S. ThyagaRajan, N. Selvamurugan, M. P. Rajesh, R. A. Nazeer, Richard W. Thilagaraj, S.

Barathi, and M. K. Jaganathan, "Biology for Engineers," Tata McGraw-Hill, New Delhi, 2012.

Reference Book:

Biology for Engineers. Arthur T. Johnson. 2010 by CRC Pres. ISBN 9781420077636

ADAMAS UNIVERSITY

Bachelor of Technology

1ST

YEAR SEMESTER – II

Module 1 - Introduction to Statics

Concept of particle and Rigid body, Vector, Introduction to Vector Algebra, Addition and subtraction

of Vectors and different laws, Lami’s theorem, Free Vector, Bound Vector, Representation of

Vectors in terms of I, j and k, Cross product and Dot product and their application, scalar.

Module 2 - Force System

Engineering Mechanics EME41104 3-0-0 3 Credits

Introduction, Force, Two-Dimensional Force system, Resolution of Force, Moment, Couple,

Varignon’s Theorem, Resultant of Forces.

Module 3 – Equilibrium Introduction, Equilibrium in Two-Dimension, Free body Concept and Diagram, Equation of

Equilibrium.

Module 4 - Distributed Force

Introduction, Center of Mass and Centroid, Centroid of Mass, Centroid of Line and Area (Triangle,

Circular section, Quadrilateral, Composite Area etc.).

Module 5 – Friction Introduction, Concept of Friction, Law of Coulomb Friction, Angle of Repose, Coefficient of

Friction, Application of Friction in Machines.

Module 6 - Moment of Inertia Mass Moment of Inertia of Symmetrical bodies, Area Moment of Inertia, Introduction, M.I of Plane

figures w.r.t an axis on its plane, M.I of plane figures w.r.t an axis perpendicular to its plane, Parallel

axis theorem.

Module 7 – Virtual Work Introduction of Virtual work, Principal of Virtual work, Application of Principal of Virtual work.

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – III

FLUID MECHANICS & ECE42101 3-0-0

3

HYDRALICS

Module 1:

Introduction to Fluid Mechanics - Fluid, Fluid types, Thermodynamic

properties, Introduction of Viscosity. Fluid statics: Forces on plane and [12]

curved surfaces, Center of pressure. Stability of floating bodies,

Metacentre.

Module 2:

Introduction; Basic equations on the continuity, momentum, and energy. Flow

[12]

through closed conduits: Laminar flow, Turbulent flow, Pipes in Series and

Parallel, Pipe Networks, Unsteady Flow. Forces on immersed bodies: Drag and

Lift. Concept of boundary layer and its growth.

Module 3 :

Weirs and Notches: Rectangular, triangular, Cippoletti, sharp crested

and broad crested weirs, submerged weirs.

Turbulent flow in circular pipes: Fluid friction in pipes, head loss due [12]

to friction. Darcy-Weisbach equation, Variation of friction factor with

wall roughness – Moody’s chart. Minor losses in pipes.

Water Hammer: Speed of pressure wave, slow and rapid closure, use of

surge tank.

Module 4 :

Steady uniform flow in open channel: Characteristics, Chezy's, Manning's and Bazin’s formulae. Hydraulically efficient cross sections. Flow through channels of circular cross sections – depths for maximum velocity and discharge.

[12]

Varied flow through open channel: Gradually varied and rapidly varied flows. Definition, Specific Energy, Critical, Sub-critical and Super-critical flows. Channel transitions - constricted or raised bed. Establishment of critical flow, Venturi flume and Parshall flume. Definition and diagram for Specific force, Hydraulic Jump.

Module 5 :

Dimensional Analysis and Model studies: Dimensions and dimensional homogeneity, Importance and use of dimensional analysis. Buckingham’s Pi theorem with applications. Geometric, Kinematic and Dynamic similarity. Non Dimensional Numbers.

[12]

Introduction to Hydraulic Turbines: Working Principles of Pelton, Francis and Kaplan turbines.

Pumps: Centrifugal pumps, performance characteristic graph – design flow rate. Working principles of positive displacement pumps, gear, reciprocating and vane pumps. Hydraulic Ram.

Text Books:

1 Fluid Mechanics Modi & Seth Standard Book House, New Delhi

2 Fluid Mechanics A.K.Jain Khanna Publishers, New Delhi

3 Fluid Mechanics & Machinery H. M. Raghunath CBS Publishers, New Delhi

Reference Books:

1 Reference Book: 2 Fluid Mechanics, Hydraulics and Fluid Machines S. Ramamrutham Dhanpat Rai

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – III

SOLID MECHANICS EME42103 3-0-0 3

Module 1:

Review of Basic Concepts of Stress and Strain: Normal stress, Shear stress, Bearing

stress, Normal strain, Shearing strain; Hooke’s law; Poisson’s ratio; Stress-strain

diagram of ductile and brittle materials; Elastic limit; Ultimate stress; Yielding;

Modulus of elasticity; Factor of safety. [12]

Beam Statics: Support reactions, concepts of redundancy, axial force, shear force and

bending moment diagrams for concentrated, uniformly distributed, linearly varying

load, concentrated moments in simply supported beams, cantilever and overhanging

beams.

Module 2:

Symmetric Beam Bending: Basic kinematic assumption, moment of inertia, elastic

flexure formulae and its application, Bending and shear stress for regular sections, shear [10]

Centre

Deflection of statically determinate beams: Fundamental concepts: Elastic curve,

moment Curvature relationship, governing differential equation, boundary conditions:

Direct integration solution.

Module 3 :

Analysis of determinate plane trusses: Concepts of redundancy, Analysis by method

of joints, Method of sections. [10]

Two Dimensional Stress Problems: Principal stresses, maximum shear stresses,

Mohr’s circle of stresses, construction of Mohr’s circle

Module 4 :

Introduction to thin cylindrical & spherical shells: Hoop stress and meridonial - [10]

stress and volumetric changes.

Torsion: Pure torsion, torsion of circular solid shaft and hollow shafts, torsional

equation, torsional rigidity, closed coil helical; springs.

Columns: Fundamentals criteria for stability in equilibrium, column buckling theory, Euler’s load for columns with different end conditions, limitations of Euler’s theory problems, eccentric load and secant formulae.

Text Books: 1 Elements of Strength of Material S. P. Timoshenko & D. H. Young EWP Pvt. Ltd 2 Engineering Mechanics of Solids E. P. Popov Pearson Education 3 Strength of Materials R. Subramanian OXFORD University Press Reference Books: 1 Strength of Material, R.K.Bansal. 2 Strength of Materials S S Bhavikatti Vikas Publishing House Pvt. Ltd.

ADAMAS UNIVERSITY B.Tech in Civil Engineering

SEMESTER – III

SURVEYING-I ECE42105 3-0-0 3 Credits

Module 1: Introduction- Various types of surveying- based on methods and

instruments, classifications, uses and necessity of geodetic surveying, photographic,

astronomy and hydrographic surveying. Diagonal scale, various types of venires, [6]

micrometres on surveying instruments, principles of surveying. Chain surveying,

instruments required for linear measurement, minor instruments for setting out right

angle

Module 2: Leveling and contouring-Definitions, technical terms, different types of

levels such as dumpy, quickset, precise, auto temporary and permanent adjustments of

dumpy and auto level. Different methods of leveling, reduction of levels, problems.

Difficulties in leveling work, corrections and precautions to be taken in leveling work.

Contour –definitions, contour interval, equivalent, uses and characteristics of contour [4]

lines, direct and indirect methods of contouring. Running a level line, L section, cross

section, methods of interpolation. Grade contour- definition, use, setting out in field.

Computation of volume by trapezoidal and prismoidal formula, volume from spot

levels, volume from contour plan.

Module 3: Plane table surveying-Definitions, uses and advantages, temporary

adjustments. Different methods of plane table surveying. Two point problem. Errors in [2]

plane table survey, use of telescopic alidade.

Module 4: Traverse Surveying-Compass: Bearings- different types, compass –

prismatic, surveyor, whole circle, reduced bearings, Local Attraction. Theodolite:-

Various parts and 88 axis of transit, technical terms, temporary and permanent

adjustments of a transit, horizontal and vertical angles, methods of repetition and

reiteration. Different methods of running theodolite traverses, Gales‟ traverse table, [6]

balancing of traverse by Bow-Ditch’s transit and modified transit rules. Problems on

one-plane and two-plane methods, omitted measurements. Precautions in using

theodolite, errors in theodolite survey. Use of theodolite for various works such as

prolongation of a straight line, setting out an angle

Module 5: Setting out works- General horizontal and vertical control, setting out of

foundation plan for load bearing and framed structure, batter board, slope and grade

stakes, setting out with theodolite. Setting out of sewer line, culvert, use of laser for

works. Setting out center line for tunnel, transfer of levels to underground work Project

/ route survey for bridge, dam and canal. Checking verticality of high rise structures. [6]

Module 6: Areas- Area of a irregular figure by Trapezoidal rule, average ordinate

rule,Simpson‟s 1/3 rule, various coordinate methods. Planimeter: types of planimeter [4]

including digital planimeter, area of zero circle, use of planimeter.

Text Books:

1 Surveying and Leveling. N.N.Basak,1st Edition ,Tata McGraw Hill, 6TH

EDITION , 2017

2 Surveying and Leveling, Vol I & II, Kanetkar and Kulkarni, 24th edition, Pune Vidyarthi Griha, Pune.

Reference Books:

1 ― Surveying, R Agor, Khanna Publishers.4TH

EDITION,2017

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – IV

STRUCTURAL ANALYSIS -I ECE42102 3-1-0 4 Credits

Module 1:

Introduction - General Concept of Static Equilibrium of Structures, Concept of Free

Body Diagram. Support and connection, Elastic and linear behavior of structure.

Principal of superposition. [4]

General Theorem relating to elastic structure - Principal of virtual work, Strain energy

stored due to axial loading. , Maxwell’s reciprocal deflection theorem, Betti’s law,

Castigliano’s 1st

theorem.

Module 2:

Analysis of statically determinate structures – Analysis of Statically Determinate

Trusses, Energy , Methods for Determination of Joint Displacements – Castigliano’s,

Theorem, Unit Load Method etc , Moment Area Theorem, Conjugate Beam Method,

Maxwell Betti’s Theorem, Method of Superposition. Application of Energy Methods to [10]

Statically Determinate Beams and Rigid Frames

Analysis of statically determinate structures – Introduction to Analysis of Statically

Indeterminate Trusses, beams, frames using Energy Methods.

Module 3:

Analysis of Arches and cable structures – Analysis of Three hinged arch.

Cable equation of the cable , Horizontal tension in the cable supported at different

levels , Length of cable support a the same level and different levels , Effect on cable [8]

due to temperature change , Three hinged stiffening girder .

Column and Struts – Theory of bucking , Euler’s theory of struts foe different support

conditions , Struts subjected to axial loads , Euler’s and rankine’s design formula ,

Struts subjected to eccentric and lateral loading , struts with initial curvature.

Module4:

Analysis of Rolling Loads and Influence Line Diagram- Analysis of bending [8]

moment and shear force subjected to a concentrated and series of rolling load , Analysis

of bending moment and shear force subjected to a udl rolling load , Maximum bending

moment and absolute bending moment concepts

Text Books: 1 Structural Analysis Volume – I, Bhavikatti, 3rd edition, Vikas Publishers, 2009. 2 Intermediate Structural Analysis, C K Wang, McGraw Hill , 3

RD EDITION , 2010

Reference Books:

1 Theory of Structures, Timoshenko & Young, Tata McGraw Hill , 4TH

EDITION, 2010

2 Structural Analysis Volume – I , Devdas Menon, Narosa Publication , 5TH

EDITION , 2009

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – IV

CIVIL ENGINEERING ECE42104 3-0-0 3

MATERIALS

Module 1:

Properties of construction materials and their evaluation (creep, elastic modulus, fatigue, impact, etc.); test methods and specifications.

[12]

Bricks: Classification, Characteristics of good bricks, Ingredients of good brick earth, Harmful substance in brick Earth, Different forms of bricks, Testing of bricks as per BIS. Defects of bricks.

Module 2:

Aggregates sources, properties, chemical reactivity; Concrete constituents, proportioning, properties in fresh and hardened state, characteristic strength, quality control (sampling, acceptance, etc.),

transportation and placing, testing (including NDT), porosity; Cement [12] chemical composition, properties such as setting, strength, fineness, hydration;

Concrete: Types, ingredients, W/C ratio, Workability, Different grades in cement concrete, Tests on cement concrete.

Module 3 :

Mortars: Classification, Uses, Characteristics of good mortar, Ingredients. Cement mortar, Lime Mortar, Lime cement mortar, special

mortars. [12] Admixtures chemical, mineral; Steel properties, types of steel, steel in

civil engineering;

Wood and Wood Products: Classification of Timber, Structure,

Characteristics of good timber, Seasoning of timber, Defects in Timber,

Diseases of timber, Decay of Timber, Preservation of Timber Testing of

Timber, Veneers , Plywood, Fibre Boards, Particle Boards, Chip Boards ,

Black Boards, Button Board and Laminated Boards, Applications of

wood and wood products , Paints, Enamels and Varnishes ,

Miscellaneous Materials.

Module 4 :

Foundations: Function of Foundations, Essential requirement of good

foundation, Different types of shallow and deep Foundations, Brick

masonry: Definitions, Rules for bonding, Type of bonds – stretcher bond,

Header bond, English bond, Flemish Bond, Comparison of English Bond [12]

and Flemish Bond (one and one and half brick thick wall), Wall, Doors

and Windows: Load bearing wall, Partition wall, Reinforced brick wall

Common types of doors and windows of timber and metal.

Module 5 :

New materials Fibre reinforced plastics (FRPs), epoxy-coated bars, etc.

with performance requirements, test methods, specifications; Bitumen [12]

source, composition, characterization, various forms, tests on bitumen;

Bituminous mix design; Soil description, engineering geology of soils

and their formation, index properties of soil, classification of soils

Text Books:

1 Plain & reinforced concrete, Vol. I, O.P. Jain & Jaikrishna

2 Concrete technology, theory and practice, M.S. Shetty.

3 Properties of concrete, Neville, El, Society & Pub.

4 Engineering Materials S.C. Rangwala ,

5 Building Construction B.C. Punmia , 2014

6 Soil Mechanics & Foundation Engineering by B C Punmia,16th Edition, Laxmi Publications

Reference Books: 1 Relevant I.S. codes. 2 Building Construction and Foundation Engineering , Jha and Sinha , 2013

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – IV

SOIL MECHANICS - I ECE42108 3-1-0 4 Credits

Module 1:

Soil as three-phase system in terms of weight, volume, voids ratio, and porosity.

Definitions: moisture content, unit weights, degree of saturation, void ratio, porosity,

specific gravity, mass specific gravity etc. Relationship between volume weight, void

ratio- moisture content, unit weight- percent air voids, saturation- moisture content,

moisture content- specific gravity etc. Determination of various parameters such as: [6]

Moisture content by oven dry method, pycnometer, sand bath method, torsional balance

method radioactivity method, and alcohol method. Specific gravity by density bottle

method, pycnometer method, measuring flask method. Unit weight by water

displacement method, submerged weight method, core cutter method, sands

replacement method.

.

Module 2:

Plasticity Characteristics of Soil-Introduction to definitions of: plasticity of soil,

consistency limits-liquid limit, plastic limit, shrinkage limit, plasticity, liquidity and

consistency indices, flow & toughness indices, definitions of activity and sensitivity.

Determination of: liquid limit, plastic limit and shrinkage limit.Use of consistency [6] limits. Classification of Soils-Introduction of soil classification: particle size

classification, textural classification, unified soil classification, Indian standard soil

classification system.Identification: field identification of soils, general

characteristics of soil in different groups.

Module 3:

Permeability of Soil-Introduction to hydraulic head, Darcy‟s law, validity of Darcy‟s

law. Determination of coefficient of permeability: Laboratory method: constant head [4]

method, falling head method. Field method: pumping- in test, pumping- out test. Permeability aspects: permeability of stratified soils, factors affecting permeability of

soil. Seepage Analysis- Introduction, stream and potential functions, characteristics of

flow nets, graphical method to plot flow nets.

Module4:

Effective Stress Principle-Introduction, effective stress principle, nature of effective

stress, effect of water table.Fluctuations of effective stress, effective stress in soils

saturated by capillary action, seepage pressure, quick sand condition.Compaction of [3]

SoilIntroduction, theory of compaction, laboratory determination of optimum moisture

content and maximum dry density. Compaction in field, compaction specifications and

field control

Module5:

Consolidation of Soil-Introduction, comparison between compaction and consolidation,

initial, primary & secondary consolidation, spring analogy for primary consolidation,

consolidation test results, basic definitions, Terzaghi‟s theory of consolidation, final [4]

settlement of soil deposits, consolidation settlement: one- dimensional method,

secondary consolidation

Module6:

Shear Strength-Principle planes parallel to the coordinate axes, Mohr‟s circle, important

characteristics of Mohr‟s circle, Mohr-Coloumb theory, types of shear test: direct shear

test, merits of direct shear test, triaxial compression tests, test behaviour of UU, CU and [3]

CD tests, relation between major and minor principal stresses, unconfined compression

test, vane shear test.

.

Module7:

Stability of Slopes-Introduction, different factors of safety, types of slope failures,

analysis of finite and infinite slopes, wedge failure Swedish circle method, friction [4]

circle method, stability numbers and charts. Soil Exploration- Introduction, methods of

investigation, methods of boring, soil samplers and sampling, number and deposition of

trail pits and borings, penetrometer tests, borehole logs, geophysical methods.

Text Books:

1 Soil Mechanics & Foundation Engineering by B C Punmia,16th Edition, Laxmi Publications . 2 Soil Mechanics & Foundation Engineering by B C Punmia,16th Edition, Laxmi Publications 3

rd

edition. Reference Books:

1 Soil Mechanics by Craig R.F., Chapman & Hall , 5th

edition , 2010

ADAMAS UNIVERSITY B.Tech in Civil Engineering

SEMESTER – V

DESIGN OF RC ECE43101

3-1-0

4 Credits

STRUCTURE

Module 1:

Reinforced Concrete Fundamentals (working Stress Method): Concept of

reinforced concrete, stress strain characteristics of concrete and steel

reinforcement, elastic theory, Reinforced concrete (RC) structures,

Loadings, analytical models for analysis and design of RC structures,

Design Methodologies singly reinforced, balanced section, under [12]

reinforced section and over reinforced section, analysis and design of

singly reinforced doubly reinforced rectangular and T-sections, design of

one way and two way slab as per IS-456, shear and bond stresses and

design for shear and bond, design of axially loaded columns, analysis of

sections subjected to bending and axial forces( tension or compression).

Module 2:

Limit state method of design: Basic concepts and IS code provisions (IS:

456 2000) for design against bending moment and shear forces; concepts

of bond stress and development length; Use of ‘design aids for

reinforced concrete’ (SP:16). [21]

Analysis, design and detailing of singly reinforced rectangular, ‘T’, ‘L’

and doubly reinforced beam sections by limit state method. Design and

detailing of one-way and two-way slab panels as per IS code provisions,

Design and detailing of continuous beams and slabs as per IS code

provisions, Shear and torsion; Bond and anchorage.

Module 3: Staircases: Types; Design and detailing of reinforced concrete doglegged staircase ,

Design and detailing of reinforced concrete short columns of rectangular [15]

and circular cross sections under axial load. Design of short columns subjected to axial load with moments (uniaxial and biaxial bending) –

using SP 16. Shallow foundations: Types; Design and detailing of reinforced concrete isolated square and rectangular footing for columns as per IS code provisions by limit state method.

Text Books: 1 Plain and Reinforced Concrete, Vol. I, Jain & Jaikrishna, Nemchand Brothers. 2 Design of Reinforced Concrete Structures, Dayaratnam P,Oxford & IBH. 3 Design of Pre-stressed Concrete Structures, Lin T Y & Ned Burns John Wiley. 4 Prestressed Concrete, Krishna Raju, Tata McGraw Hill. 5. Reinforced concrete design by pillai and menon. Reference Books: 1 Prestressed Concrete, Evans R H & Benett E W, Chapman & Hall.

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – VII

STRUCTURAL ANALYSIS - ECE43103 3-1-0

4 Credits

II

Module 1:

Redundant structures: Concepts of statical and kinematic indeterminancy of

beams, trusses and portal frames; Application of second theorem of Castigliano

and method of consistent deformation for analysis of propped cantilever, fixed [20]

beams and continuous beams (maximum two degree of indeterminacy) for

simple loading cases.

Arches: Introduction. Three hinged arch-analysis and influence line. Two

hinged arch and fixed arch --application of unit load method, Castigliano’s 2ND

method and elastic centre method, Influence line for arches.

Module 2:

Portal frame: Solution by- unit load method, Castigliano’s method.

Moment distribution method - solution of continuous beam, effect of [18]

settlement and rotation of support, frames with or without side sway.

Slope Deflection Method – Method and application in continuous beams and

Frames. Cables & Suspension bridges with three hinged stiffening girders.

Module 3 :

Curved beams- analysis Hooks, Rings and Bow girders. Un-symmetrical

bending. [22]

Column analogy –method, application Stiffness and carry over factors for non-

prismatic members.

Kani’s method: application to indeterminate beams and frames

Text Books:

1 Theory of structures: by S.P.Timoshenko 2 Theory of structures: by S.Ramamurthum. 3. Statically indeterminate structures: by C.K.Wang 4. Basic structural analysis: by C.S. Reddy Reference Book: 1. Matrix method of structural analysis: by M.B.Kanchi 2. Mechanics of structures: by Thadani 3. Indeterminate structural analysis: by Kinney

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – V

SOIL MECHANICS - II ECE43105 3-1-0 4 Credits

Module 1:

Lateral Earth Pressures Theories- Introduction: applications of earth pressure theories,

different types of earth pressure at rest, active and passive pressure. Rankine’s Earth

Pressure Theory, active earth pressure and passive earth pressure for horizontal and

inclined backfill including the direction of failure Planes for cohesion-less and cohesive

soils. Coulomb’s Wedge Theory: Coulomb’s active pressure in cohesion-less soils, [6]

expression For active pressure, Coulomb’s passive earth pressure. Rebhann’s Construction for

Active Pressure, Culmann’s graphical solutions for active soils, Wedge Method, passive pressure

by friction circle method for cohesion-less and cohesive soils. .

Module 2:

Earth Retaining Structures- Rigid and flexible retaining structures, stability analysis of

retaining walls, cantilever retaining Walls, construction details, drainage and wall [4]

joints.

Module 3:

Bearing Capacity of Shallow Foundation- Definitions of ultimate bearing capacity,

gross, net and safe pressures, allowable bearing pressure, types of shallow foundations

modes of failures. Bearing capacity theories: Rankine’s approach, Prandtl’s approach

and Terzaghi’s approach, concept behind derivation of equation, general bearing

capacity equation, bearing capacity equations for square and circular footings, factors

[8]

influencing bearing capacity, performance of footings in different soils, Vesic’s chart,

ultimate bearing capacity in case of local shear failure. Plate load test in detail with

reference to IS1888 and its applications and estimation of settlements, bearing capacity

based on Standard Penetration Test.

Module4:

Axially Loaded Pile Foundations: 4.1 Introduction to pile foundations, necessity of pile

foundation, classification of piles, construction methods of bored piles, concrete bored

piles, driven cast in-situ piles. Pile capacity based on static analysis, piles in sand, piles [6]

in clay, dynamic methods and their limitations, in- situ penetration tests and pile load

test as per IS 2911 specifications, negative skin friction. Pile groups ultimate capacity

of groups, settlement of pile groups in sand and in clay as per IS 2911 and critical depth

method..

Module5:

Consolidation of Soil-Introduction, comparison between compaction and consolidation,

initial, primary & secondary consolidation, spring analogy for primary consolidation,

consolidation test results, basic definitions, Terzaghi‟s theory of consolidation, final [10]

settlement of soil deposits, consolidation settlement: one- dimensional method,

secondary consolidation.

Module6:

[5]

Underground Conduits- Classes of underground conduits, load on a ditch conduit,

settlement ratio, ditch condition and projection condition, imperfect ditch conduit.

Module7:

[5]

Open Cuts: Difference in open cuts and retaining walls, apparent pressure diagrams,

average apparent pressure diagrams for sand and stiff clay, estimation of loads on struts.

Text Books: 1 Soil Mechanics & Foundation Engineering by B C Punmia,16th Edition, Laxmi Publications . 2 Soil Mechanics & Foundation Engineering by B C Punmia,16th Edition, Laxmi Publications 3

rd

edition. Reference Books:

1 Soil Mechanics by Craig R.F., Chapman & Hall , 5th

edition , 2010

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – V

TRANSPORTATION ECE43107

3-0-0 3 Credits

ENGINEERING-I

Module 1:

Highway planning-Classification of roads, brief history of road development in India,

present status of roads in India, road patterns, saturation systems, highway alignment:

basic requirements for an ideal alignment, factors governing highway alignment, [4]

highway location surveys and studies, highway alignment in hilly areas, drawings and

reports, highway project preparation.

.

Module 2: Geometric design of highways-Terrain classification, design speed, vehicular characteristics, highway cross-section elements Sight distance: introduction to sight distance, reaction time, analysis of safe sight distance, analysis of overtaking sight distance, intersection sight distance. Design of horizontal alignment: horizontal curves,

design of super elevation and its provision, radius at horizontal curves, widening of [4]

pavements at horizontal curves, analysis of transition curves. Design of vertical alignment:

different types of gradients, grade compensation on curves, analysis of vertical curves, summit

curves, valley curves. Intersection: at grade and grade separated intersections, speed change

lanes, Canalization, Design of rotary intersection and mini roundabout.

Module 3: Traffic engineering & control-Traffic engineering definitions: functions, organization and importance, necessity of understanding the behavior of road user and vehicle

characteristics, human factors governing the road user behavior- power performance and other vehicular characteristics. Traffic studies and surveys: Speed studies:

presentation of data, journey time and delay studies, uses and various methods, relative merits and demerits Vehicular volume counts: types, various available methods, relative merits and demerits, planning of traffic counts, vehicle occupancy surveys. Origin: [8] destination surveys, need and uses, various available methods, checks for accuracy, presentation of data. Parking surveys: needs and types. Study of various photographic techniques available for traffic studies. Traffic signs and marking: types, location, height etc., miscellaneous traffic control aids like roadway delinators, hazard markers, object marker, speed breakers, rumble strips etc., Street lighting: needs, definitions, laws of illumination, methods of discernment, glare problem, light lantern arrangement, types of lamps, planning and designing.

Module4:

Pavement materials- Stone aggregates: desirable properties, tests, requirements of

aggregates for different types of pavements. Bituminous materials: types, tests on [6]

bitumen, desirable properties, selection of grade of bitumen. Bituminous mix design:

principle, methods, modified binders.

Module5:

Design of pavements-Types of pavements, comparison of different types of pavements,

functions of pavement components, pavement design factors, design wheel load,

equivalent single wheel load, repetition of loads, equivalent wheel load factors, strength

characteristics of pavement materials, climatic variation; design of flexible highway

pavement as per IRC approach, design of flexible airport pavements, Stresses in rigid

highway pavements, critical load positions, stresses due to loads, stresses due to [8]

temperature change, combined loading and temperature stresses, Joints in rigid

pavements: transverse joints, longitudinal joints, fillers and sealers.

Text Books:

1 L R Kadiyali, N B Lal, Principles and practice of highway engineering, Khanna Publications,

2005.

2 Principles Of Transportation Engineering, Partha Chakroborty, PHI Learning, 1st edition

Reference Books: 1 Principles of Highway Engineering and Traffic Analysis, 4th Edition, Fred L. Mannering, Scott S.

2 Morlok, E.R., an Introduction to Transportation Engineering and Planning, McGraw Hill, NY,

2010

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – VI

DESIGN OF STEEL ECE43102 3-1-0

4 Credits

STRUCTURE

Module 1: Materials and Specification:-Rolled steel section, types of

structural steel, specifications. Limit states and design philosophy; [6]

partial safety factors and load combinations; Analysis and design

methods.

Module 2 : Structure connections: Riveted, welded and bolted including

High strength friction grip bolted joints. – types of riveted & bolted

joints, assumptions, failure of joints ,efficiency of joints, design of bolted

riveted & welded joints for axial load. [12]

Eccentric connection:- Riveted & bolted joints subjected to torsion &

shear, tension & shear, design of riveted, bolted & welded connection.

Module 3: Design of tension members based on net section including

shear lag effects, staggered holes and block shear; Design of compression members for flexural and flexural torsional buckling, Column formula,

Local buckling and buckling class, End restraints and effective length [10]

factor; Role of plate buckling, Plastic hinge, Classification of section: plastic, compact, semi-compact, slender.

Module 4: Design strength of laterally supported beams, Shear buckling

strength Post-critical method, Shear moment interaction, Design strength

of laterally unsupported beams, Lateral torsional buckling, Effect of [10]

restraints and effective length; Effect of axial load on flexure behaviour,

Cross-section yielding and member instability, PM interaction and

moment amplification, Biaxial bending

Module 5: Plate girders: Design of webs & flanges, Concepts of

curtailment of flanges – Riveted & welded web stiffeners, web flange

splices - Riveted, welded& bolted.

Gantry Girder: Design gantry girder considering lateral buckling – I.S [10]

code provisions.

Plastic Analysis of Steel Beam Section.

Text Books:

1 Limit State Design of Steel Structures IS:800-2007, V.L.Shah and Veena Gore, Structures

Publications, 2010

2 Design of Steel Structures, S.S.Bhavikatti, I.K. International Publishing House Limited, 2010. 3.

Reference Books: 1 Design of Steel Structures, N. Subramanian, Oxford University Press, 2010 2 Relevant IS Codes

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – VI

WATER RESOURCE ENGINEERING ECE43106 3-1-0 4 Credits

Module 1

Introduction: Irrigation, water resources in India, need of irrigation in India, [4]

development of irrigation in India, impact of irrigation on human environment,

irrigation systems: minor and major, command area development.

Module 2:

Hydrology: hydrologic cycle, rainfall –runoff process, factors affecting runoff, runoff [7]

hydrograph, runoff computations, flood discharge calculations, unit hydrograph

method, S-hydrograph.

Module 3:

Water requirement of crops: Crops and crop seasons in India, cropping pattern, duty

and delta; Quality of irrigation water; Soil-water relationships-soil characteristics [6]

significant from irrigation considerations, root zone soil water, infiltration, consumptive

use, irrigation requirement, frequency of irrigation; Methods of applying water to the

fields: surface, sub-surface, sprinkler and trickle / drip irrigation.

Module 4:

Ground water and well hydrology: Ground water resources, occurrence of ground

water, methods of ground water exploration, well irrigation; Well hydraulics: steady [4]

state flow in wells, equilibrium equations for confined and unconfined aquifers, aquifer

tests, design of water wells.

Module 5: [8]

Distribution system: Canal systems, alignment of canals, canal losses, estimation of

design discharge. Design of channels-rigid boundary channels carrying clear and

sediment laden water, alluvial channels carrying clear and sediment laden water,

Kennedy‟s and Lacey‟s theory of regime channels. Canal outlets: non-modular, semi-

modular and modular outlets. Waterlogging: causes, effects and remedial measures.

Lining of canals-economics of lining, types of lining. Drainage of irrigated lands:

necessity, methods.

Module 6: [4]

Canal structures: Surface and sub-surface flow considerations for design of canal

structures: hydraulic jump, seepage forces, uplift forces. Canal falls, cross regulator,

distributary head regulator, canal escapes: types, components and design considerations,

Cross drainage works: need, types, design considerations.

Module 7: [4] Canal headworks: Weir and barrage, different units of headworks, types of weirs, sediment control in canals, river training for canal headworks. Theories of seepage for design of weirs:

Bligh‟s creep theory, Lane‟s weighted creep theory, Khosala‟s method of independent variables.

Module 8: [4]

Dams and spillways: Embankment dams, Classification, selection of site for dam,

design considerations, estimation and control of seepage, slope protection. Gravity

dams: forces on gravity dams, causes of failure, stress analysis, elementary and

practical profile, structural joints, keys and water seals, galleries, outlets. Arch and

buttress dams-types. Spillways: components of spillways, types, terminal structures,

types of gates for spillway crests; Reservoirs-Types, capacity of reservoirs, yield of

reservoir, reservoir regulation, sedimentation, economic height of dam, selection of

suitable site, flood routing.

Text Books:

1 G L Asawa, Irrigation Engineering, Wiley Eastern

2 S K Garg, Irrigation Engineering & Hydraulic Structures, Khanna Publishers.

3 P N Modi, Irrigation Engineering & Hydraulic Structures

Reference Books:

1 J D Zimmerman, Irrigation, John Wiley & Sons

2 Varshney, Gupta & Gupta, Theory and Design of Irrigation Structures, Nem Chand & Bros.

3 Punmia B C & Pande B B Lal, Irrigation Engineering and Water Power Engineering, Laxmi Publications.

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – VI

ENGINEERING GEOLOGY ECE43110 3-0-0 3

Module 1:

Geology and its importance in Civil Engineering.

Mineralogy: Definition, internal and external structure of minerals, study of crystals,

Classification and physical properties of minerals.

Classification of rocks: Igneous rocks: Origin, mode of occurrence, forms & texture, [12]

classification and engineering importance. Sedimentary rocks: Process of

sedimentation, classification and engineering importance. Metamorphic rocks: Agents

and types of metamorphism, classification and engineering

Importance.

Module 2:

Weathering of rocks: Agents and kinds of weathering, soil formation & classification

based on origin.

[10]

Geological work of rivers: Origin and stages in the system, erosion, transportation and

deposition. Structural geology: Introduction to structural elements of rocks, dip &

strike, definition, description, classification of folds, faults and joints, importance of

geological structures in Civil Engineering.

Module 3 :

Earthquakes and seismic hazards: Causes and effects, seismic waves and

seismographs, Mercelli’s intensity scale and Richter’s scale of magnitude.

[10]

Engineering properties of rocks: Porosity, permeability, compressive strength, tensile

strength and abrasive resistance.

Rocks as construction materials: Qualities required for building and ornamental

stones, foundations, concrete aggregate, railway ballast, road metal, pavement, flooring

and roofing.

Module 4 :

[15]

Geophysical exploration: Methods of Geophysical Exploration, electrical resistivity

method field procedure – sounding and profiling, electrode configuration, and

interpretation of resistivity data.

Geophysical surveys in ground water and other Civil Engg. Projects.

Applied Geology: Surface and subsurface geological and geophysical investigations in major Civil Engg. Projects. Geological studies of Dams and reservoir sites, Geological studies for selection of tunnels and underground excavations.

Landslides: Types of landslides, causes, effects and prevention of landslides.

Text Books:

1 Engineering and General Geology Parvin Singh Katson publishing house Delhi. 2 Engineering Geology for Civil Engineers D. Venkat Reddy, Oxford, IBH, 3 Principles of petrology Tyrell Asia, Bombay Reference Books:

1 Structural Geology Marland P. Billings Wiley eastern Prentice-Hall, U.S.A. 2 Ground Water hydrology Todd D.K. John Wiley & Sons, Second edition,

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – VII

ENVIRONMENTAL ECE44101 3-1-0 4 Credits

ENGINEERING-I

Module 1:

Water:- Water Supply systems, Need for planned water supply schemes, Sources of

Water, Water demand and Potable, industrial and agricultural water requirements,

Components of water supply system; Transmission of water, Distribution system, [6]

Various

valves used in W/S systems, service reservoirs and design.

Module 2:

Sewage- Domestic and Storm water, Quantity of Sewage, Sewage flow variations.

Conveyance of sewage- Sewers, shapes design parameters, operation and maintenance

of sewers, Sewage pumping; Sewerage, Sewer appurtenances, Design of sewerage

systems. Storm Water- Quantification and design of Storm water; Sewage and Sullage, [4]

Pollution due to improper disposal of sewage, National River cleaning plans, recycling

of sewage – quality requirements for various purposes.

.

.

Module 3:

Air - Composition and properties of air, Quantification of air pollutants, Monitoring of [6]

air pollutants, Air pollution- Occupational hazards, Urban air pollution automobile

pollution, Chemistry of combustion, Automobile engines, quality of fuel, operating

conditions and interrelationship. Air quality standards, Control measures for Air

pollution, construction and limitations

Module4:

Noise- Basic concept, measurement and various control methods. [6]

Module5:

Solid waste management-Municipal solid waste, Composition and various chemical and

physical parameters of MSW, MSW management: Collection, transport, treatment and

disposal of MSW. Special MSW: waste from commercial establishments and other

urban areas, solid waste from construction activities, biomedical wastes, Effects of solid

waste on environment: effects on air, soil, water surface and ground health hazards. [8] Disposal

of solid waste-segregation, reduction at source, recovery and recycle. Disposal methods-

Integrated solid waste management. Hazardous waste: Types and nature of hazardous waste as

per the HW Schedules of regulating authorities.

Text Books: 1 Introduction to Environmental Engineering by P. Aarne Vesilind, Susan M. Morgan, Thompson

/ Brooks/Cole; Second Edition 2008. 2 Introduction to Environmental Engineering, Vesilind, PWS Publishing Company 2000 Reference Books: 1 Integrated Solid Waste Management, Tchobanoglous, Theissen & Vigil. McGraw Hill Publication 2 Environmental Engineering by H.S.Peavy, D.R. Rowe, G.Tchobanoglous; 2007, Tata-Mcgraw

Hill.

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – VII

PRESTRESSED CONCRETE ECE43110 3-0-0 3 Credits

Module 1:

Introduction to pre-stressed concrete: basic concept and general principles, [10]

materials used and their properties, methods and techniques of pre-stressing, pre-

stressing systems, loss of pre-stress.

Module 2:

Analysis of pre-stressed concrete sections: loading stages and computation of [8]

section properties, critical sections under working load for pre-tensioned and post-

tensioned members, load balancing method of analysis of pre-stressed concrete beams.

Module 3:

Design of pre-stressed concrete sections for flexure: general philosophy of design,

design approaches in working stress method and limit stress method, critical [12]

conditions for design, limit state of collapse in flexure, permissible stresses in concrete

and steel, kern points, choice and efficiency of sections, cable profiles and layouts, cable

zone, deflections of pre-stressed concrete members.

Module 4:

Design for shear: calculation of principle tension under working load,permissible [8]

principle tension, shear strength calculation under limit state of collapse for both

sections cracked and un-cracked in flexure.

Module 5:

End zone stresses in pre-stressed concrete members: pretension transfer bond, [10]

transmission length, end block of post-tensioned members

Module 6:

Design of pre-stressed concrete beams: design of simply supported pre-tensioned and [12] post tensioned slabs and beams, introduction to application of pre-stressing to continuous beams, linear transformation and concordancy of cables.

Text Books:

1 Design of Reinforced Concrete Structures, Dayaratnam P, Oxford & IBH , 5TH

EDITION,2010

2 Pre-stressed Concrete, N. Krishna Raju..7TH

EDITION , 2015

Reference Books:

1 Design of Reinforced Concrete Structures, Dayaratnam P, Oxford & IBH , 5TH

EDITION , 2005

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – VII

DESIGN OF BRIDGE ECE43112 3-0-0

3 Credits

STRUCTURE

Module 1:

Introduction, - Definition and Basic Forms, Component of bridge,

classification of bridge, short history of bridge development. I.R.C Loads.

Analysis of IRC Loads, Impact factors, Other loads to be considered, [12]

Importance of Hydraulic factors in Bridge Design.

Reinforced concrete solid slab bridge: Introduction, General design features,

Effective width method. Simply supported and cantilever Slab Bridge, analysis

and design

Module 2:

Box Culvert: Introduction, Design method and Design example.

Beam and Slab Bridges Introduction, Design of interior panel of slab. Pigeauds [18]

method, Design of longitudinal girder, Calculation of longitudinal moment,

design example.

Module 3 :

Balanced Cantilever Bridges: General Features, Arrangement of supports,

design features Articulation, Design example. [20]

Steel Bridges: General features, types of stress, Design example.

Plate Girder Bridge: Elements, design, lateral bracing, Box- girder

Module 4 :

Composite Bridges: General aspects, method of construction, analysis of [20]

composite section, shear connectors, design of composite beam.

Cable Stayed Bridge: General features, Philosophy of design.

Text Books: 1 Principle & Practice of Bridge Engineering S.P. Bindra– DhanpatRai Pub. 2 Essentials of bridge engineering D.J. Victor. 3. Bridge engineering Ponnuswamy. 4. Bridge engineering by Krishnaraju. Reference Book: 1. Design of concrete bridges by Aswani, Vizirani , Ratwani. 2. Design of steel structures Arya&Ajmani.

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – VII

DESIGN OF BRIDGE ECE43112 3-0-0

3 Credits

STRUCTURE

Module 1:

Introduction, - Definition and Basic Forms, Component of bridge,

classification of bridge, short history of bridge development. I.R.C Loads.

Analysis of IRC Loads, Impact factors, Other loads to be considered, [12]

Importance of Hydraulic factors in Bridge Design.

Reinforced concrete solid slab bridge: Introduction, General design features,

Effective width method. Simply supported and cantilever Slab Bridge, analysis

and design

Module 2:

Box Culvert: Introduction, Design method and Design example.

Beam and Slab Bridges Introduction, Design of interior panel of slab. Pigeauds [18]

method, Design of longitudinal girder, Calculation of longitudinal moment,

design example.

Module 3 :

Balanced Cantilever Bridges: General Features, Arrangement of supports,

design features Articulation, Design example. [20]

Steel Bridges: General features, types of stress, Design example.

Plate Girder Bridge: Elements, design, lateral bracing, Box- girder

Module 4 :

Composite Bridges: General aspects, method of construction, analysis of [20]

composite section, shear connectors, design of composite beam.

Cable Stayed Bridge: General features, Philosophy of design.

Text Books: 1 Principle & Practice of Bridge Engineering S.P. Bindra– DhanpatRai Pub. 2 Essentials of bridge engineering D.J. Victor. 3. Bridge engineering Ponnuswamy. 4. Bridge engineering by Krishnaraju. Reference Book: 1. Design of concrete bridges by Aswani, Vizirani , Ratwani. 2. Design of steel structures Arya&Ajmani.

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – VII

WASTE MANAGEMENT ECE43114 3-0-0 3 Credits

Module 1:

Industrial Wastes: Nature and characteristics, Prevention and Control, Tools for clean processes: reuse, recycle, recovery, source reduction, raw material substitution Process modification, Flow sheet analysis, Energy and resources audit, Waste audit, [24] emission inventory and waste management hierarchy for process industries, Zero discharge.

.

Module 2:

Environmental indicators, Industrial ecology and ecoparks, rules and regulations, Case studies: Dairy, Fertilizer, Distillery, Pulp and Paper, Iron and steel, Metal plating, [21] Refineries, Thermal power plants, etc.

Text Books:

1 Environmental Engineering by H.S.Peavy, D.R. Rowe, G.Tchobanoglous; 2007, Tata-Mcgraw

Hill. 2 Integrated Solid Waste Management, Tchobanoglous, Theissen & Vigil. McGraw Hill Publication

. Reference Books: 1 Introduction to Environmental Engineering, Vesilind, PWS Publishing Company 2000

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – VIII

ENVIRONMENTAL ECE44102 3-0-0

3 Credits

ENGINEERING-II

Module 1:

Sewage and drainage: Definition of some common terms used in sanitary

engineering. Systems of sanitation, systems of sewerage’s. Types of sewage. [22]

Sources of sanitary sewage. Estimating the quantity of sanitary sewage and

storm sewage.

Design of sewers - Nomograms, partial flow diagrams. Testing of sewer lines

Sewer appurtenances. Pumping of sewage. House drainage.

Module 2:

Characteristics of sewage: Physical, Chemical and Biological. Test on sewage;

Solids, dissolved oxygen, biochemical oxygen demand, stability and relative

stability, chlorides, sulphide, nitrogen. pH value, grease, oil and fat. Biological [18]

tests, carbon, nitrogen and sulphur cycles.

Solid waste disposal: Quality and quantity of refuse, Collection and conveyance

of solid wastes. Disposal of solid waste by composting, and other methods,

Salvaging, grinding and discharging into sewers.

Module 3 :

Disposal by other methods: Oxidation pond, oxidation ditch, aerated lagoon,

septic tank, Iimhoff tank, Disposal by dilution, irrigation and farming, stream

sanitation. [20]

Treatment of sewage: Primary treatment - screen, grit chamber, detritus tank,

skimming tank, plain sedimentation with coagulation. Secondary treatment -

Filtration, normal rate trickling filters, high rate trickling filters activated sludge

process, aeration units, types of activated sludge process, sludge digestion.

Functional design of primary and secondary treatment units. 10h\ References

Text Books:

1 Environmental Engineering S.K. Garg -Khanna Pub 2 Water Supply, Waste Disposal & Enviormental Pollution Engineering – A . K . Chatterjee

– Khanna Pub 3. Water Supply & Waste Water Disposal –G . M . Fair ,J . C . Geyer ,D . A . Okun . –Jhon

Wiley & Sons. 4. Water Supply and Sanitary Engineering By G.S.Birdi Reference Book: 1. Manual of Water Supply & treatment - A Government of India Publication. 2. Water supply sanitary engineering by G.S. Birdi

ADAMAS UNIVERSITY

B.Tech Civil Engineering

SEMESTER – VIII

HYDRAULICS ECE44104

3-1-0

4 Credits

STRUCTURE.

Module 1:

Diversion Head works: Necessity, Difference between weir and Barrage, Type of

Weirs, Selection of site, layout and description of each part, Effects of construction of a

weir on the river regime, causes of failure of weirs on permeable foundation and their

remedies.

[12]

Theories of seepage and Design of weirs and Barrages: Failure of Hydraulic

Structures Founded on Pervious foundations: i) By piping ii) By Direct uplift, Bligh’s

creep theory of seepage flow, Khosla’s theory & concept of flownets, concept of exit

gradient and critical exit gradient, Khosla’s method of independent variable for

determination of pressures and exit gradient for seepage below a weir or a barrage,

necessary corrections, examples.

Module 2:

Hydraulic structures for canals: Canal falls – necessity, locations, types and

description of Ogee fall, Trapezoidal-notch fall, Syphon well drop. Examples.

Cross-Drainage Works: Necessity, types, selection of a suitable type (Introduction

[10]

only).

Dam (General): Definition, classification of Dams, factors governing selection of type

of dam, selection of suitable site for a dam.

Module 3 :

Earthen Dams: Introduction, Types of Earthen Dams, Methods of Construction, [10]

Causes of failure, Design Criteria, Determination of line of seepage or phreatic line in

Earthen Dam, seepage control in Earthen Dam, Examples.

Module 4 :

[15]

Gravity Dam: Definition, Typical cross- section, Forces acting on Gravity Dam,

Combination of

forces for design, Mode of failure and criteria for structural stability of Gravity Dams, Principal and shear stresses. Elementary profile of a Gravity Dam, Concept of High and low Gravity Dam, Examples.

Text Books:

1 G L Asawa, Irrigation Engineering, Wiley Eastern 2 S K Garg, Irrigation Engineering & Hydraulic Structures, Khanna Publishers. 3 P N Modi, Irrigation Engineering & Hydraulic Structures

Reference Books:

1 J D Zimmerman, Irrigation, John Wiley & Sons 2 Varshney, Gupta & Gupta, Theory and Design of Irrigation Structures, Nem Chand & Bros.

3 Punmia B C & Pande B B Lal, Irrigation Engineering and Water Power Engineering, Laxmi Publications.

ADAMAS UNIVERSITY

B.Tech in Civil Engineering SEMESTER – VIII

EARTHQUAKE ENGINEERING ECE44109 3-0-0 3 Credits

Module 1: Introduction: Definitions of basic problems in dynamics, static versus dynamic loads, different types of dynamic loads, un-damped vibration of SDOF system, natural

frequency and periods of vibration, damping in structure, response to periodic loads, [10]

response to general dynamic load, response of structure subject to gravitational motion, use of Fourier series for periodic forces.

Module 2: Direct determination of frequencies and mode shapes: orthogonality principle, approximate methods for determination of frequencies and mode shapes, modal error of [12] forced vibration of MDOF system, modal analysis, applications to multistoried rigid frames subject to lateral dynamic loads.

Module 3:

Seismological background: Seismicity of a region, earthquake faults and waves, [10] structure of earth, plate tectonics, elastic-rebound theory of earthquake, Richter scale, measurement of ground motion, seismogram.

Module 4: Characterization of ground motion: earthquake response spectra, factors influencing

response spectra, design response spectra for elastic systems, peak ground acceleration, [8]

response spectrum shapes, deformation, pseudo-velocity, pseudo-acceleration response spectra,

peak structural response from the response spectrum, response spectrum characteristics.

Module 5: Deterministic earthquake response: types of earthquake excitation, lumped SDOF

elastic systems, translational excitation, lumped MDOF elastic systems, translational

excitation time history analysis, multistoried buildings with symmetric plans, [12]

multistoried buildings with unsymmetric plans, torsional response of symmetric plan building,

distributed-parameter elastic systems, translational excitation, combining maximum modal

responses using mean square response of a single mode, SRSS and CQCC combination of modal

responses.

Module 6: I. S. code method of seismic analysis: seismic co-efficient method and its limitation, [4] response spectrum method, I. S. code provision for seismic analysis of buildings and

water towers.

Module 7:

Case Study: Review of damages during past earthquakes and remedial measures, [4] seismic design considerations, allowable ductility demand, ductility capacity, reinforcement detailing for members and joints.

Text Books: 1 Structural Dynamics-An introduction to Computer Methods, Roy R. Craig. 2 Dynamics of Structures, Anil K. Chopra, Prentice Hall, India. 3 Dynamics of Structures, Cloguh & Penzien, Tata McGraw Hill, New Delhi 4 Structural Dynamics, John M. Biggs, Tata McGraw Hill, New Delhi 5 Fundamentals of Earthquake Engineering, N. M. Newmarks & E. Rosenblueth, Prentice Hall. 6 Earthquake Design Practice for Building, D. Key, Thomas Telford, London, 1988. 7 Earthquake Engineering, R. L. Wiegel, 2nd Edition, Prentice Hall, London, 1989 Reference Books: 1 Design of Multistoried Buildings for Earthquake Ground Motions, J. A. Blume, Portland Cement

Association, Chicago, 1961. 2 Proceedings on World Conference on Earthquake Engineering, 1956-2000. 3 I. S. codes No. 1893, 4326, 13920. (Latest Editions).

ADAMAS UNIVERSITY B.Tech in Civil Engineering

SEMESTER – VIII

DESIGN OF TALL BUILDING ECE44111 3-0-0 3 Credits

Module 1: Introduction : Necessity of Tall Buildings, Design Philosophy, Strength and

Stability, Creep, Shrinkage and Temperature Effects, Fire, Foundation Settlement and Soil-Structure Interaction Loadings : Gravity loading, Wind loading, Earthqua Loading, 12 Combination of Loadings.

Module 2: Structural Forms : Braced-Frame Structures, Rigid Frame Structures, In

filled-Frame Structures, Shear Wall Structures, Wall Frame Structures, Tubular

Structures, Core Structures, Floor Systems – Reinforced Concrete : One-Way slab, [18]

Two-way slab, Floor Systems – Steel Framing, One-way Beam System, Two-Way

Beam System, Three-Way Beam System, Composite Steel-Concrete Floor Systems

Module 3: Modeling for Analysis: Approaches to analysis, High-rise behaviour,

modeling for approximate analysis, Modeling for Accurate Analysis. Stability of High-

rise buildings, buckling analysis of Frames. Dynamic Analysis: Dynamic Response to [15]

Wind Loading, Dynamic Response to Earthquake Loading

Module 4: Foundations and foundation-superstructure interaction; Wind/ earthquake

effects and design for ductility; Damping systems; Asymmetric structures and twisting [15]

of frames

Text Books:

1 Tall Building Structures: Analysis and Design Bryan S. Smith and Alex Coull John Wiley &

Sons, Inc, New York, 1991 Designing Tall Buildings Mark Sarkinsian, Routledge, New York, 2012

2 Designing Tall Buildings Mark Sarkinsian, Routledge, New York, 2012

Reference Books: 1 Structural Frameworks Clyde T. Morris and Samuel T. Carpenter John Wiley

ADAMAS UNIVERSITY B.Tech Civil Engineering

SEMESTER – VIII

FINITE ELEMENTMETHOD ECE43104 3-1-0 4 Credit

Module 1(Boundary value problems and Weighted residual methods):

Introduction, weighted residual forms, weak formulation, Galerkin method, examples of [12]

one, two, and three-dimensional problems, examples of continuum problems.

Module 2 (Variational methods):

Establishment of natural variational principles, approximate solution of differential

equations by Rayleigh-Ritz method, the use of Lagrange multipliers, general variational [8]

principles, least-square method.

Module 3 (Finite Element analysis of one dimensional problems):

One dimensional second order equations, discretisation of domain into elements,

generalised coordinates approach, derivation of elements equations, assembly of

elements equations, imposition of boundary conditions, solution of equations, Cholesky [8]

method, extension of the method to fourth order equations and their solutions, time

dependant problems and their solutions.

Module 4 (Finite Element analysis of two dimensional problems):

Second order equation involving a scalar-valued function, Variational formulation,

Finite element formulation through generalised coordinates approach, Triangular

elements and quadrilateral, Elements matrices and vectors, Assembly of element [10]

matrices, boundary conditions, solution techniques.

Module 5 (Isoparametric formulation):

The concept of mapping, isoparametric formulation, numerical integration, mapping and [12]

its use in mesh generation.

Module 6 (Application to field problems in two dimension): [12]

Equations of elasticity, plane elasticity problems, axis symmetric problems in elasticity,

time dependent problems in elasticity, incompressible fluid flow.

Text Books: 1 Zienkiewicz, O.C., and Morgan, K., Finite Element Approximation, John Wiley & Sons, 1983.

Reddy, J.N., The Finite Element Method for Engineers, John Wiley & Sons, 1995. 2 An Introduction to the Finite Element Method, McGraw Hill, 2006. Huebner, K.H., Thornton,

E.A., and Byrom, T.G. Reference Books: 1 The Finite Element Method for Engineers, John Wiley & Sons, 1995.