First Year
Subject
|
Hrs./week |
Units |
Theo. |
Prac. |
Tut. |
B.E.4101
|
Engineering Mechanics |
3 |
- |
1 |
6 |
B.E.4102
|
Mathematics (I) |
3 |
- |
1 |
6 |
B.E.4103
|
Building Materials
Technology |
2 |
1 |
- |
5 |
B.E.4104
|
Engineering Drawing |
1 |
3 |
- |
5 |
B.E.4105
|
Engineering Geology |
2 |
- |
- |
4 |
B.E.4106
|
Principles of Computers |
1 |
2 |
1 |
4 |
B.E.4107
|
Principles of Highway and
Bridge Engineering
|
1 |
- |
- |
2 |
B.E.4109
|
Human Rights and Public
Freedoms
|
1 |
- |
- |
2 |
B.E.4109
|
English Intro.
|
1 |
-- |
1 |
2 |
B.E.4110
|
Workshops |
- |
6 |
- |
6 |
Total
|
15 |
12 |
4 |
42 |
31 |
B.E. 4101
Engineering Mechanics
|
Theory:
3hrs./ Week
Tutorial:
1hr./ Week
|
Statics:
1- Introduction to
scalar and vector quantities, forces, moments, couples. |
16 |
2- Resultants of force
systems. |
16 |
3- Equilibrium:
Free-body diagrams,
equilibrium of bodies by planar and three dimensional
system of forces with applications. |
16 |
4- Friction:
Coefficient of
friction, angle of friction, applications. |
10 |
5- First and second
moments of inertia:
Centroid, center of
gravity and center of pressure, theorems or propositions
of Pappus, second moments of inertia, products of
inertia of areas, polar moment of inertia, transfer of
coordinates. |
20 |
Dynamics:
6- Kinematics-absolute
motion:
Rectilinear motion,
angular motion and absolute motion of particles using
linear and polar coordinates, absolute motion of a
particle on a curve in one plane using normal and
tangential components. |
16 |
7- Kinetics, force,
mass, acceleration, Newton’s law of motion, equations of
motion of a particle (translation and rotation),
reversed effective forces and couples. |
16 |
8- Introduction to
work and energy. |
10 |
|
|
|
B.E. 4102
Mathematics I
|
Theory: 3hrs./ Week
Tutorial: 1hr./ Week |
1- Revision:
Trigonometry, graphs,
coordinates, equations of straight line and circle,
function domain, range, inverse of a function, absolute
value, limits, definition and theories, lim (sin
f) /
f, infinity,
differentiation and integration of algebraic function.
|
20 |
2- Determinants:
definitions and properties, solution of a system of
equations (Cramer’s Rule). |
4 |
3- Vectors:
definitions and representations, vector components and
the unit vector. |
20 |
4- Transcendental
function (trigonometric, inverse trigonometric, natural
algorithmic, exponential and power functions):
definitions, properties, differentiation and integration
graphs. |
12 |
5- Conic sections:
(parabola, ellipse and hyperbola). |
8 |
6- Hyperbolic
functions: definitions, properties, derivatives and
integrals. |
8 |
7- Methods of
integration: powers of trigonometric functions,
integrals involving
,
integrals with ax2+bx+c, partial fraction,
integration by parts, the substitution u= tan x/2,
further substitution, improper integral. |
24 |
8- Application of
definite integrals (areas, volumes, length of the curve
and surface areas). |
12 |
9- Complex numbers:
definitions, Argand diagram, multiplication and
division, De Moivre’s theorem, roots. |
8 |
10- Polar coordinates:
graphs and plane area. |
4 |
|
|
|
B.E. 4103 Building
Materials Technology |
Theory: 2hr./ Week
Practical: 1hr./ Week |
1-Structure of matter:
Atomic structure,
types of bonding. |
2 |
2- Mechanical
properties of materials:
Stress, deformation,
strain, Hooke’s law, general expression for strain,
toughness, ductility, and thermal properties.
|
14 |
3- Types of materials:
Metallic materials,
non metallic materials and ceramic materials. |
2 |
4-Tests:
Tensile, compressive,
flexural, torsion, impact, hardness, creep and fatigue. |
10 |
5- Metal:
Classification,
composition, properties, uses, standard tests and
specifications. |
8 |
6- Bricks:
Classification,
manufacture, properties of brick, durability, standard
tests and specifications. |
6 |
7- Bonding materials:
Classification,
chemical composition, manufacture, properties and uses
of common bonding materials, standard tests and
specifications. |
6 |
8- Timber:
Classification,
properties, seasoning, types of defects, standard tests. |
8 |
9-Plastics: properties
and classifications, methods of manufacturing, moldings,
plastic binders, fields of application of plastics. |
4 |
Laboratory
Tests
|
1- Bricks:
Dimensions,
efflorescence, water absorption, compressive strength. |
4 |
2-Terrazo tiles:
Dimensions, water
absorption, modulus of rupture. |
4 |
3- Steel:
Tensile test,
compressive test, modulus of elasticity. |
2 |
4- Bonding materials-
Gypsum:
Fineness, standard
consistency, setting time, soundness, mechanical
resistance, static bending. |
10 |
5- Timber:
Static bending,
compression parallel and perpendicular to the fiber,
tensile test, shear test. |
10 |
|
|
|
B.E. 4104
Engineering Drawing
|
Theory: 1hr./ Week
Practical: 3hr./ Week |
1- Introduction:
definition of engineering drawing, applications of
engineering drawing in industrial fields. |
4 |
2- Graphic instruments
and their use. |
4 |
3- Arabic and Latin
lettering. |
4 |
4- Drawing of all
types of lines. |
8 |
5- Drawing of some
simple types of decorations. |
4 |
6- Drawing of ellipse
using different methods. |
4 |
7- Drawing of
different tangents and curves. |
4 |
8- Drawing scales.
|
4 |
9- Ortho
graphic-drawing, projections. |
8 |
10- Isometric drawing. |
8 |
11- Free-hand drawing. |
4 |
12- Projection by
European method. |
8 |
13- Determination of
the third projection based on two known projections. |
12 |
14- Isometric drawing
based on three known projections. |
12 |
15- Sections. |
8 |
16- Drawing of plans
for civil engineering applications. |
8 |
17- Descriptive
geometry. |
16 |
|
|
|
B.E. 4105
Engineering Geology
|
Theory:
2hrs./ Week
|
1- Introduction:
Relationship between
geology and civil engineering, earth structure (crust,
mantle, core), geological cycle. |
4 |
2- Minerals and rocks:
-Minerals: formation,
classification, crystal forms, identification.
-Rocks:
classification, nature, texture, igneous, sedimentary
and metamorphic rocks, natural rock cycle. |
6 |
3- Soil:
Weathering, soil
formation, classification, transported and residual
soils, mineral composition, soils of Iraq. |
4 |
4- Structural geology:
Types of earth
movements, basic definitions, folds, faults, joints, and
their types. |
4 |
5- Topographic and
geological maps:
General concepts,
importance, components, construction of each map,
examples and applications. |
6 |
6- Physical and
engineering properties of rocks:
- Physical properties
of rocks (density, porosity, void ratio, dry and
saturated unit weight), multimineral rocks. Mathematical
examples and applications.
- Mechanical
properties: Rock deformation, elastic moduli, mechanical
properties of rocks (compressive, tensile, and shear
strength), earth stresses. Mathematical examples and
applications. |
4 |
7- Surface water and
river geologic work:
Water movement,
discharge and other hydraulic parameters with their
mathematical determination, river geologic work
(erosion, transportation and deposition), types of river
deposits. Mathematical examples and applications. |
4 |
8- Ground water:
Sources, permeability
and porosity, effects of rock types, vertical
distribution of ground water, types of aquifers,
(confined and unconfined), Darcy's law, case study for
unconfined aquifers, ground water movement effect of
geological structures on ground water, springs and their
types, hydrogeology of Iraq. Mathematical examples and
applications. |
6 |
9- Site
investigations:
Fundamental concepts,
stages of site investigations. Geophysical methods
(electric, seismic, Ground Penetrating Radar (GPR),
electromagnetic, gravity, magnetic) with their
applications and uses in civil engineering. Mathematical
examples and applications. |
6 |
10- Geological
problems related to civil engineering:
Soil creep,
landslides, rock avalanches, erosion, deposition, their
causes and effects, effect of ground water, applications
and engineering solutions. |
6 |
11- Effects of
geological structures on structural projects:
joints, folds, and
faults, applications. |
6 |
12- Other phenomena:
Volcanoes and
earthquakes, their effects and predictions. |
4 |
|
|
|
B.E. 3106 Principles of
Computers
|
Theory: 1 hr./ Week
Practical: 2 hrs./
Week
Tutorial: 1 hr./ Week
|
1- Computer
definition: (Computer generation, computer components,
numerical systems, algorithms and charts). |
3 |
2- File, definition,
types and names, operating system (MS-DOS): explain,
internal and external commands. |
3 |
3- Introduction to
WINDOWS, Desktop, using the mouse, My Computer, closing
any open window, temporary closing. |
3 |
4- Zooming any window,
creating new folder, select folder, find folder or file,
copying from any folder to another, delete files or
folders. |
2 |
5- Microsoft office
·
Microsoft World
·
Microsoft Excel
·
Microsoft Powerpoint |
5 |
5- Quick basic
programming. |
4 |
6- Introduction to
AutoCAD:
Definition of the
AutoCAD graphics window and the way of determining point
through window, explain the commands. |
2 |
7- Limits, Status,
Zoom, Pan, Snap, Grid, Osnap, Ortho. |
4 |
8- Line, Rectangle,
Circle, Arc. |
3 |
9- Examination. |
1 |
|
|
|
B.E. 4107 Principles
of Highway and Bridge Engineering |
Theory:
1hr./ Week
|
1- General
introduction to highways and bridges. |
1 |
2- Classifications of
highways and bridges. |
2 |
3- Construction
materials of highways and bridges. |
2 |
4- Types of pavement. |
3 |
5- Route location of
highways. |
1 |
6- Geometric design of
highways. |
3 |
7- Specifications of
highway works. |
3 |
8- Introduction to
traffic engineering. |
2 |
9- Types of bridges. |
3 |
10- Loads on bridges. |
3 |
11- Specifications of
bridge works. |
4 |
12- Planning of
intersections and interchanges. |
3 |
|
|
|
B.E. 4108
Human Rights and Public Freedoms
|
Theory: 1hr./ Week
|
1- Origins of civil
rights and freedom, including: legislation for civil
rights, understanding civil rights, philosophy of civil
rights, economical conception of civil rights, etc. |
3 |
2- Legal basis for the
rule of law, including: influence of the constitution on
the legality and guarantee of civil rights, civil rights
laws & their application, organization by authority &
their behaviour during state of emergency, etc. |
3 |
3- General Freedoms
guarantees, including legal action, study of French
legal system, basic principles of civil rights, etc. |
3 |
4- Equality, including
historical development of equality, gendre equality,
equality of creed & race, etc. |
2 |
5- Basic Freedoms,
individual civil rights, freedom of culture & thought,
economic freedom in society, etc. |
2 |
6- Basic civil rights,
including security of society & individual, refusal to
accept retroactive laws, individual rights before &
after the French revolution and in an empire, Algerian
struggle for freedom, etc. |
4 |
7- Freedom of movement
of people. |
2 |
8- Freedom of thought,
including freedom of opinion &belief, separation between
state & religious establishment, freedom of the press,
freedom of organization, freedom of public
demonstration, historical development, etc. |
6 |
9- Freedom of labour,
etc. |
2 |
10- Freedom of owning
property, capitalistic & socialist understanding of
ownership. |
1 |
11- Freedom of trade
and industry including constitutional requirements,
commercial freedom, etc. |
1 |
12- Other Freedoms
including, forming political parties, third world
application of civil rights, advances in scientific&
technical aspects of civil rights. |
1 |
|
|
|
B.E.
4110Workshops
|
Practical:
6 hrs./ Week
|
The workshop training
program is designed to satisfy the following objectives:
·
Teaching safety rules and regulations on-site in an
industrial environment.
·
Proper use of working tools, instruments, and machines.
·
Introducing basic workshop practices, production, labor,
and time-requirements of workshop operations.
The students are
introduced to training programs in nine workshops:
electrical, welding, forging, fitting, turning and
milling, carpentry, plumbing, auto-mechanics, and
casting.
The student is to
spend 18 hours of training in every workshop.
|
Second Year
Subject
|
Hrs./week |
Units |
Theo. |
Prac. |
Tut. |
B.E.4201
|
Strength of Materials |
3 |
- |
1 |
6 |
B.E.4202
|
Mathematics (II) |
3 |
- |
1 |
6 |
B.E.4203
|
Concrete Technology |
2 |
2 |
- |
6 |
B.E.4204
|
Engineering Surveying |
2 |
2 |
- |
6 |
B.E.4205
|
Fluid Mechanics |
2 |
1 |
1 |
5 |
B.E.4206
|
Construction of Highways
and Bridges
|
2 |
- |
1 |
4 |
B.E.4207
|
Computer Programming |
1 |
2 |
- |
4 |
B.E.4208
|
Engineering Statistics |
1 |
- |
1 |
2 |
Total
|
16 |
7 |
5 |
39 |
28 |
B.E. 4201 Strength of
Materials
|
Theory: 3 hrs./ Week
Tutorial: 1 hr./ Week |
1- Analysis of
deformable bodies:
a)
Forces &
equilibrium requirements.
b)
Deformation & compatibility conditions.
c)
Load-deformation relationships.
d) Introduction to
statically determinate and statically indeterminate
systems. |
12 |
2- Axial force , shear
and bending moments:
a)
Loading
and deformation.
b)
Loading
systems and their resultants.
c)
Shear
forces and bending moments by section method.
d)
Axial
force, shear and bending moment diagrams; a direct
approach.
e)
Differential equations of equilibrium and applications. |
12 |
3- Stress and axial
loads:
a)
Definition of stress.
b)
Axial
stresses and temperature effects.
c)
Bending
stresses in beams.
d)
Bending
stresses in compound sections.
e)
Bending
in nonsymmetrical beams.
f)
Shear
stresses.
g)
Shear
center. |
21 |
4- Torsion:
a)
Torsion
for solid-circular sections.
b)
General
application of torsion-torque diagram.
c)
Strain
energy in torsion.
d)
Torsion
for solid non-circular sections.
e)
Torsion
for thin tube sections. |
9 |
5- Shells: Thin walled
vessels. |
3 |
6- Transformation of
stress and strain:
a)
Plane
stress.
b)
Stress
axis transformation- Mohr circle.
c)
Strain
axis transformation. |
21 |
7- Deflection of
beams:
a)
The
governing differential equation for deflection of
elastic beam (limited conditions).
b)
Direct
integration method.
c)
Moment
area method. |
12 |
|
|
|
B.E. 4202 Mathematics II
|
Theory: 3 hrs./ Week
Tutorial: 1 hr./ Week |
1- Partial
differentiation:
a)
Functions of two or more variables.
b)
Directional derivative.
c)
Chain
rule for partial derivatives.
d)
Total
differential.
e)
Maxima,
minima, and saddle points.
f)
Higher
order derivatives. |
18 |
2- Differential
equations:
a)
First
order; separable, homogeneous, linear & exact.
b)
Second
order equations reducible to first order.
c)
Linear
second order homogeneous equations with constant
coefficients.
d)
Linear
second order nonhomogeneous equations with constant
coefficients: variation of parameters, and undetermined
coefficients method.
e)
Higher
order linear equations with constant coefficients.
|
15 |
3- Vector analysis:
a)
Equations: lines, line segments and planes in space.
b)
Vector
products.
c)
Velocity
& acceleration.
d)
Curvature, torsion, & the TNB frame. |
12 |
4- Complex numbers &
functions:
a)
Complex
numbers.
b)
Complex
functions.
c)
Derivatives.
d)
The
Cauchy-Riemann equations.
e)
Complex
series.
f)
Elementary functions. |
12 |
5- Multiple integrals:
a)
Double
integrals.
b)
Area by
double integrals.
c)
Area,
moments and centers of mass.
d)
Double
integrals in polar form.
e)
Triple
integrals.
f)
Green’s
theorem & Stoke’s theorem. |
12 |
6- Matrices:
a)
Matrix
addition & multiplication.
b)
Inverses
of square matrices.
c)
Eigen
vectors & Eigen values. |
9 |
7- Infinite series:
a)
Definitions.
b)
Geometric series.
c)
Series
tests.
d)
Series
with nonnegative terms.
e)
Power
series. |
9 |
8- Polar, cylindrical,
& spherical coordinates. |
3 |
|
|
|
B.E. 4203 Concrete
Technology
|
Theory: 2 hrs./ Week
Practical: 2 hrs./
Week
|
1- Cement:
Manufacturing, Chemical
composition, hydration of cement, properties of cement,
effect cement compound on its properties, types of
cement. |
8 |
2- Aggregate:
General classification,
sampling, properties and tests of aggregate, bulking of
sand, deleterious substances in aggregate, soundness of
aggregate, sieve analysis, grading curves and
requirements, practical grading, maximum size of
aggregate. |
6 |
3- Fresh concrete:
Consistency, workability
and factors affecting workability, methods of
workability test, segregation and bleeding, mixing,
compaction, concreting in hot weather, ready mixed
concrete, pumped concrete. |
4 |
4- Strength of concrete:
Types of strength,
factors affecting strength, curing of concrete, bond
strength between concrete and steel reinforcement. |
6 |
5- Concrete mix design:
Basic considerations,
British method of mix design, American method of mix
design, design of special concrete. |
12 |
6- Durability of
concrete:
Permeability of concrete,
resistance of concrete to sulfate and acid attacks,
effects of frost on fresh and hardened concrete,
corrosion of reinforcement. |
6 |
7- Elasticity, shrinkage,
and creep:
Modulus of elasticity and
factors affecting it, shrinkage and factors affecting
it, creep and factors affecting it. |
4 |
8- Admixtures:
Types of admixtures, uses
of admixtures. |
4 |
9- Introduction to new
types of concrete:
Light weight concrete,
high performance and high strength concrete, fiber
reinforced concrete, self compacted concrete, any other
new types. |
10 |
Laboratory tests |
1- Cement:
- Consistency, initial
and final setting times tests.
- Soundness test,
compressive strength test. |
|
4 |
4 |
2- Aggregate:
- Sampling and density
test.
- Specific gravity and
absorption tests.
- Shape and surface
texture test.
- Sieve analysis of fine
and coarse aggregates. |
|
4 |
4 |
4 |
4 |
3- Fresh concrete:
- Slump test and casting
cubes of different sizes.
- Compaction factor test
and casting cylinders of different sizes..
- V-B time test and
casting prisms of different sizes.
- Samples tests (cubes,
cylinders, prisms).
- Test for effect of
aggregate conditions on workability of fresh concrete. |
|
4 |
4 |
4 |
4 |
4 |
4- Design of concrete
mixes:
- Making trial mixes
designed by British method.
- Making trial mixes
designed by American method. |
|
4 |
4 |
5- Admixtures:
Tests for the effect of
superplastisizers and other new admixtures on properties
of fresh and hardened concrete. |
|
8 |
|
|
|
B.E. 4204 Engineering
Surveying
|
Theory: 2hrs./ Week
Practical:
2hrs./ Week
|
1- General concepts of
surveying:
- General definition
of surveying, basic principles of surveying, types of
surveying.
- Basic principles and
steps of surveying and setting out of constructions. |
4 |
2- Measurements and
errors:
- Types of
measurements, units of measurements, scale.
- Errors; types of
errors, sources of errors, mistakes, precision and
accuracy. |
2 |
3- Adjustment of
measurements:
- Most probable value
and the standard error for direct measurements.
- Most probable value
and the standard error for indirect measurements; law of
error propagation, weight of measurements.
- Basic principles of
the least squares method, adjustment of one indirect
measurement by the least square method. |
6 |
4- Linear
measurements:
Taping methods;
systematic error in taping, measuring obstructed
distances, other uses of tape. |
2 |
5- Leveling:
- Direct leveling;
level, basic parts and principles.
- Direct differential
leveling; systematic errors, field procedure, types of
differential leveling.
- Adjustment of
differential leveling by the least squares method.
- Direct profile
leveling; field procedure, adjustment of profile
leveling, computation of cut and fill. |
8 |
6- Midterm exam. |
2 |
7- Angles and
directions:
- Angles; types of
angles, types of horizontal angles.
- Directions;
direction of a line, meridian, azimuth, bearing. |
2 |
8- Angles measuring
instruments:
- Basic parts and
principles, optical-reading theodolites, digital
theodolite, total station.
- Measuring horizontal
angles; repetition method, direct method.
- Measuring vertical
angles, double centering, First term exam. |
6 |
9- Traversing:
- Introduction;
methods of control survey, accuracy standards and
specifications, basic concept of traversing, types of
traverses.
- Field procedure of
traversing; measuring the length of traverse sides;
using tape, using EDM or total station, measuring the
horizontal angle of the traverse; traversing by angle to
the right, traversing by deflection angles.
- Computation of
horizontal coordinates of the traverse stations.
- Adjustment of
horizontal coordinates of the traverse stations. |
6 |
10- Midterm exam. |
2 |
11- Areas:
Methods of measuring
area, area by coordinators method, area by trapezoidal
rule, area by Simpson's rule, area by planimeter. |
2 |
|
|
|
B.E. 4204 Engineering
Surveying (Continued)
|
Theory: 2hrs./ Week
Practical:
2hrs./ Week
|
12- Topographic
surveying:
Basic concept of
topographic surveying
- Contour lines; contour
interval, representation of earth topography by contour
map.
- Characteristics of
contour lines.
- Basic methods for
contouring; direct method, indirect methods, grid
method, irregular method.
- Locating topographic
details by radiation methods (radial traversing,
trigonometric leveling); radiation by total station,
radiation by stadia method, radiation by tangential
method.
- Radiation using
theodolite and substance bar.
- Topographic surveying
by GPS. |
8 |
13- Volume of earthwork:
- Fields of application
in civil engineering; routs survey, land leveling,
borrow-pit, construction of pipelines.
- Volumes using
cross-sections; types of cross-sections, area of
cross-sections, volume by end-area method, volume by
prizimoidal method.
- Volumes using the grid
method (borrow-pit).
- Land leveling; land
leveling for construction project, agricultural Land
leveling. |
6 |
14- Horizontal curves:
- Introduction, types of
horizontal curves, types of circular curves, simple
circular curves; degree of the curve, basic elements of
simple circular curve.
- Circular curve
formulas.
- Circular curve
stationing.
- Field procedure of
circular curve layout by deflection angles using total
station or (theodolite and tape). |
4 |
15- Vertical curves:
- Basic concept and uses
of vertical curves.
- Equal-tangent vertical
parabolic curve; equation of the curve, location and
elevation of high or low point on the curve, staking a
vertical parabolic curve.
- Computation for an
unequal-tangent vertical curve.
- Second term exam. |
4 |
Experiments |
1- Basic principles of
surveying and setting out of constructions;
determination the location of a point. |
2 |
2- Basic principles of
surveying and setting out of constructions; establishing
the location of a point. |
2 |
3- Measuring obstructed
distance using tape. |
2 |
4- Level; basic parts and
principles, setting up, reading level rods. |
2 |
5- Differential leveling
using level; starting and closing at the same benchmark. |
2 |
6- Differential leveling
using level; starting from a benchmark and closing at
another one. |
2 |
7- Profile leveling using
level. |
2 |
8- Theodolite/ total
station. |
2 |
9- Basic parts and
principles, setting up, measurements of H.C.R. and
V.C.R. |
2 |
10- Measuring horizontal
angles; repetition method. |
2 |
11- Measuring horizontal
angles; direct method. |
2 |
12- Mid term exam |
2 |
13- Measuring horizontal
angles; closing the horizon. |
2 |
14- Measuring vertical
angles. |
2 |
15- Trigonometric
leveling. |
2 |
16- First term exam. |
2 |
|
|
|
Experiments
(Continued) |
17- Traversing with
total station (or theodolite and tape) by measuring
angle to the right; traverse start and close at the same
horizontal control point. |
2 |
18- Traversing with
total station (or theodolite and tape) by measuring
angle to the right; traverse start at control point and
close at another horizontal control point. |
2 |
19- Traversing with
total station (or theodolite and tape) by measuring
deflection angles |
2 |
20- Mid term exam. |
2 |
21- Measurement of
area from map; by planimeter, trapezoidal rule and
coordinate method, Simpson rule, and coordinate method. |
2 |
22- Measurement of
area from map; by planimeter. |
2 |
23- Measurement of
area, trapezoidal rule and coordinate method, Simpson
rule, and coordinate method. |
2 |
24- Locating
topographic details by radiation methods (radial
traversing, trigonometric leveling); radiation by total
station, radiation by stadia method, radiation by
tangential method. |
2 |
25- Radiation using
theodolite and substance bar. |
2 |
26- Staking out a
building using total station (or theodolite and tape). |
2 |
27- Setting out of
horizontal curves by deflection angles using total
station (or theodolite and tape). |
2 |
28- Setting out of
horizontal curves by deflection angles using total
station (or theodolite and tape). |
2 |
29- Staking vertical
curves using level. |
2 |
30- Second term exam. |
2 |
B.E. 4205 Fluid Mechanics
|
Theory: 2 hrs./ Week
Practical: 1 hr./ Week
Tutorial: 1 hr./ Week |
1- Introduction:
History, properties of
fluids, units, mass density, weight density, relative
density, specific volume, compressibility, elasticity,
viscosity, surface tension, capillarity, and vapor
pressure. |
8 |
2- Fluid statics:
Pressure-density-height relationship, absolute & gauge
pressures, manometers, forces on submerged surfaces,
applications. |
8 |
3- Kinematics of fluid
motion:
Steady & unsteady
flow, streamlines, uniform & nonuniform flow, velocity &
acceleration. |
8 |
4- Basic laws:
Continuity equation,
energy equation, Euler equation, Bernoulli equation,
energy line, hydraulic grade line, pumps & turbines,
conservation of momentum law, impulse, momentum
equations, pipe bends, applications. |
12 |
5- Flow of real fluid:
Laminar & turbulent
flow, fluid flow past solid boundaries, velocity
distribution & its significance, shear stress in laminar
& turbulent flow, resistance force & energy dissipation,
flow establishment of boundary layers, laminar &
turbulent boundary layers, applications. |
8 |
6- Flow in pipes:
Flow in pipes, steady
uniform flow in pipes, experimental results about
friction coefficient, laminar flow in pipe, turbulent
flow in pipe, turbulent flow in smooth & rough pipes,
flow in commercial pipes, head losses in noncircular
pipes, minor losses, divided flow, multiple pipes,
applications. |
8 |
7- Open channel flow:
Definitions of flow in
open channels, steady uniform flow, optimum section,
specific energy, critical depth, specific energy in
nonrectangular channels, design of sections, stability
theory. |
8 |
Experiments
|
1- Calibration of
gauge pressure. |
3 |
2- Pressure on
submerged surface. |
3 |
3- Discharge through
orifice. |
3 |
4- Discharge over
weirs. |
3 |
5- Flow though Venturi
meters. |
3 |
6- Head losses in
pipes. |
3 |
7- Jet impact. |
3 |
8- Reynold’s number in
pipes. |
3 |
9- Pitot tube test. |
3 |
10- Hydraulic jump |
3 |
|
|
|
B.E. 4206 Construction of
Highways and Bridges
|
Theory: 2 hrs./ Week
Tutorial: 1 hr./ Week |
1- Introduction to
construction of highways. |
2 |
2-
Flexible pavement
layers. |
4 |
3- Rigid pavement
layers. |
4 |
4- Stages of highway
construction. |
10 |
5- Construction
equipment. |
4 |
6- Laboratory tests in
highway construction. |
6 |
7- History evolution
of bridges. |
2 |
8- Types of bridges. |
4 |
9- Methods of bridges
construction. |
10 |
10- Details of main
components of bridges (superstructure and substructure). |
10 |
11- Forces
distribution and components. |
4 |
|
|
|
B.E. 3207 Computer
Programming
|
Theory: 1 hr./ Week
Practical: 2 hrs./
Week |
Visual Basic language |
4- Introduction to
Visual Basic language. |
1 |
5- Forms: Control
tools, name selection of the control tools. |
1 |
6- Explorer project,
properties, events. |
1 |
7- Project, save
project, applications. |
1 |
8- Files and projects,
exercises. |
1 |
9- Menus, their
building and writing the code. |
1 |
10- Dialogue box,
message box, file dialogue box, line dialogue box, color
dialogue box, printer dialogue box. |
2 |
11- Main object for
visual box statements, data, static data, numerical
letteral, variables, direct certainty statement.
|
1 |
12- General formula of
notification, notification of statics mathematical and
logical procedure. |
2 |
13- Additional
procedure on letteral chain, notice statement by using
the quick window, printing and simple statement for
words. |
1 |
14- Control statement
for decisions:
(IF-------THEN)
statement, (IF---------THEN) statement multilines. |
2 |
15-
(IF-----THEN-----ELSE) statement, (IF-----THEN-----ELSE)
multiple and similar statement. |
2 |
16- (CASE) statement,
(SWITCH) function, (IFF) function, (CHOOSE) function. |
2 |
17- Looping statement
(FOR-----NEXT). |
1 |
18- Looping statement
(DO-----WHILE-----LOOP).
Looping
statement (DO-----LOOP-----WHILE). |
2 |
19- (NESTED LOOP)
statement. |
1 |
20- Matrix definition,
notification matrix statement. |
5 |
21- functions and sub
procedures |
2 |
21- Files, special
statements of the sequence files. |
1 |
|
|
|
B.E. 4208 Engineering
Statistics
|
Theory: 1hr./ Week
Tutorial: 1hr./ Week
|
1- Definitions and
fundamentals:
Definition of
statistics, importance of statistics, types of
statistics, basic definition, population, sample, random
sample, …..etc. |
2 |
2- Frequency
distributions:
Raw data, class
interval and class limits, histogram and polygon,
relative and cumulative frequencies, applications. |
4 |
3- Measure of central
location:
Mean, median, mode,
midrange, comparison for the measurement of central
tendency. |
3 |
4- Measure of
variation and dispersion:
Measure of variation,
range, mean deviation, the variance and standard
deviation, coefficient of variation, measure of skewness
and peakedness, application. |
3 |
5- Probability theory:
Relative frequency
Venn diagram, intersection, union, conditional
probability, independent events, mutually exclusive
events, mathematical expectation, permutations and
combinations, applications. |
3 |
6- Distributions:
Discrete distribution;
binomial distribution and Poisson distribution,
continuous distribution; normal distribution, chi-square
distribution, applications. |
4 |
7- Sampling theory:
Sampling methods,
sampling distributions, and sampling distribution of
means, differences and sums, applications. |
3 |
8- Estimation theory:
Estimation and
estimator, efficiency, sufficiency and consistency,
confidence level in estimation, confidence level for
means, proportions, sums and differences, choice of
sample size, applications. |
3 |
9- Statistical
decision theory:
Test of hypothesis and
significance, statistical hypothesis, statistical errors
for the regions of rejection and acceptance, tests. |
2 |
10- Regression and
correlation:
Choice of curves,
least square methods, correlation, applications. |
3 |
|
|
|
Third Year
Subject
|
Hrs./week |
Units |
Theo. |
Prac. |
Tut. |
B.E.4301
|
Soil Mechanics |
3 |
1 |
1 |
7 |
B.E.4302
|
Engineering Analysis and
Numerical Methods |
3 |
- |
1 |
6 |
B.E.4303
|
Remote Sensing and GIS
|
2 |
2 |
- |
6 |
B.E.4304
|
Theory of Structures |
3 |
- |
1 |
6 |
B.E.4305
|
Highway Design
|
2 |
1 |
1 |
5 |
B.E.4306
|
Pavement Design |
2 |
1 |
- |
5 |
B.E.4307
|
Railway Engineering |
2 |
- |
- |
4 |
B.E.4308
|
Reinforced Concrete
Design |
2 |
- |
1 |
4 |
B.E.4309
|
Traffic Engineering
|
1 |
- |
1 |
2 |
Total
|
20 |
5 |
6 |
45 |
31 |
B.E. 4301
Soil Mechanics
|
Theory: 3hrs./ Week
Tutorial: 1hr. / Week
Practical: 1hr. / Week |
1- Geotechnical
Properties:
Formation of natural
sedimentation, Grain size distribution, Clay minerals,
Soil Classification, Weight-volume relationship, Soil
compaction. |
15 |
2- Hydraulic
Properties:
Permeability field and
lab. |
3 |
3- Steady state Flow:
One and
two-dimensional flow, flow net, piping or boiling. |
15 |
4- Principle of
effective stress:
Total stress,
effective stress, pore water pressure. |
12 |
5-Stresses within a
Soil Mass, geostatic stresses, stresses due to external
loads. |
6 |
6- Consolidation
theory and settlement:
Terzagi theory and
assumptions, consolidation test, consolidation analysis.
|
18 |
7- Shear strength of
soils:
Mohr-Coulomb theory,
laboratory tests, direct shear test, triaxial test,
coefficient of pore water pressure. |
15 |
8- Lateral earth
pressure. |
6 |
Laboratory
Tests
|
1-
Water
content.
2-
Atterberg limits.
3-
Specific
gravity.
4-
Sieve
analysis.
5-
Hydrometer analysis.
6-
Compaction test.
7-
Field
density test. |
8-
Permeability test.
9-
Unconfined compression test.
10-
Direct
shear test.
11-
Triaxial
compression test.
12-
Consolidation test.
13-
California Bearing Ratio test. |
|
|
|
|
B.E. 4302 Engineering
Analysis and Numerical Methods
|
Theory:
3hrs./ Week
Tutorial: 1hr./ Week |
Engineering
Analysis
|
1- Ordinary differential
equations- applications:
1-1 Applications of first
order differential equations.
1-1-1 Salt concentration
in tanks.
1-1-2 Discharge through
orifices.
1-2 Applications of
second and higher order differential equations.
1-2-1 Mechanical
vibration.
1-2-2 Elastic stability.
1-2-3 Newton’s 2nd
law of motion. |
9 |
2- Simultaneous linear
differential equations.
2-1 Cramer’s rule.
2-2 Applications.
2-2-1 Salt concentration
in tanks.
2-2-2 Mechanical
vibration- stiffness formulation.
2-2-3 Frequency of
structures by the energy conservation law.
|
9 |
3- Second & higher order
linear differential equations with no constant
coefficients.
3-1 Euler method or (Z=ln
x) method.
3-2 Power series
(Frobenous method). |
6 |
4- Fourier series:
4-1 Periodic functions &
Fourier coefficients.
4-2 Even & odd functions.
4-3 Half range expansion. |
6 |
5- Partial differential
equations:
5-1 Separation of
variables method.
5-2 Applications:
5-2-1 Heat equations.
5-2-2 D’Alembert solution
of the wave equation.
5-2-3 Laplace equation. |
9 |
6- Matrices:
6-1 Review.
6-2 Solution of linear
ordinary differential equations.
6-2-1 Row transformation
method (matrix inversion).
6-2-2 Gauss elimination.
6-2-3 Gauss-Jordan
method.
6-2-4 Gauss-Siedel
method.
6-2-5 Cholesky’s method
or L-U method.
6-2-6 Eigen values &
Eigen vectors. |
9 |
Numerical Methods |
7- Introduction to
numerical methods:
7-1 Difference table.
7-2 Differences & divided
differences. |
6 |
8- Linear interpolation:
8-1 Newton-Gregory
interpolation polynomial.
8-2 Newton-Divided
difference formula.
8-3 Lagrange
interpolating polynomial. |
6 |
9- Numerical integration:
9-1 Trapezoidal and
Simpson’s rules.
9-2 Gaussian quadrature. |
6 |
10- Solution of
non-linear equations:
10-1 Newton-Raphson
method.
10-2 Indeterminate
coefficients.
10-3 Indeterminate
weights. |
6 |
11- Numerical solution of
ordinary differential equations (initial value
problems):
11-1 Taylor series.
11-2 Euler method.
11-3 Modified Euler
method.
11-4 Runge-Kutta method-4th
order. |
9 |
12- Finite differences-
boundary value problems. |
9 |
|
|
|
B.E. 4303 Remote
Sensing and GIS |
Theory:
2hr./ Week
Practical: 2hr./ Week |
1- Concept of Remote
Sensing.
|
2 |
2- Sources of Energy,
Fundamental Properties of Electromagnetic Radiation,
Photo. Properties, Aerial Survey Sources. |
2 |
3- Aerial survey Eng.,
applications, type of photographs, different between
vertical aerial photographs & maps, Indications on
aerial photographs. |
2 |
4- Vertical aerial
photograph, Eng. Relations for vertical aerial
photograph photographic coordinate system, scale of
vertical aerial photographs. |
2 |
5- Ground coordinates
from a vertical photograph, relief displacement on a
vertical photograph, flying height of a vertical
photograph. |
2 |
6- Parallax equations
(Relations between parallax & point height), flight
design. |
2 |
7- An Ideal Remote
Sensing System, Elementary Air Survey, Characteristics
of film and lens, Characteristics of sensor platforms. |
2 |
8- Black& White film,
Color film, Infrared film, Film Exposure, Exposure
Curves, Resolutions types, Ground Resolutions. |
2 |
9- Optical system
analysis,
Radiance Properties for Aerial Photographs & Image
Characteristics. |
2 |
10- Thermal graphic
(Thermal Imaging),
Heat Transfer, Blackbody
Radiation, Total Radiant Existence, Radiation From Real
Materials. |
2 |
11- Interaction
Mechanisms within the Atmosphere,
Interaction Of Thermal
Radiation With Terrain Elements. |
2 |
12- Thermal Energy
Detectors, Thermal Radiometers, Thermal Scanners,
Geometric Characteristics Of Thermal Scanner Imagery. |
2 |
13- The Multi band Camera
(or the Multi-spectral Frame Camera System), MSS
Operation and Design Considerations. |
2 |
14- Micro Wave Sensing. |
2 |
15- Imaging Radar
systems, Operation of Side Looking Airborne Radar, Image
Characteristics, Imaging Radar Properties. |
2 |
16- Passive Microwave
Elements, Passive Microwave Sensors. |
2 |
17- Remote Sensing From
the Space. |
2 |
18- A History of Remote
sensing from the space, Satellite characteristics around
the earth. |
2 |
19- Interpretation
satellite Image. |
2 |
20- Platform and systems
for Acquisition images, Meteorological satellites. |
2 |
21- Digital Image
Processing. |
2 |
22- Initial Processing
for Digital Data, Image processing system, Image
structural. |
2 |
23- Image Enhancement,
Image Rectification & Restoration. |
2 |
24- Instruments and
equipments for Image Processing, extraction Data. |
2 |
25- Using Remote Sensing
Techniques in Road Eng. By evaluation for highway
Alignment. |
2 |
26- Using Remote Sensing
Techniques in environment Eng. And environment analysis
and estimation Pollution Problems. |
2 |
27- Using Remote Sensing
Techniques in Resources Management and Hydrologic
application. |
2 |
28- Remote sensing
applications. |
1 |
29- Climate analysis,
cartographic, Cities analysis, Urban Planning. |
1 |
30- Agriculture analysis,
Forests. |
1 |
31- Introduction in
Geographic Information Systems (GIS) and applications. |
1 |
32- Introduction in
Global Position System (GPS) and applications. |
1 |
33- Ground Penetration
Radar (GPR) and its applications. |
1 |
|
|
|
B.E. 4303 Remote
Sensing and GIS |
Theory:
2hr./ Week
Practical: 2hr./ Week |
Computer Applications
|
1- |
Definition &
Components of GIS, Arc GIS, Overview of Arc GIS (Arc
Map, Arc Catalog, Arc Toolbox). |
2 |
2- |
Maps & Categories,
Fundamentals of Arc Map, Image viewer, Layers, data
frames, displaying data. |
2 |
3- |
Map Projection &
Categories. |
2 |
4- |
Table of Content, Subset
Image. |
2 |
5- |
Size & Shape of Earth,
Scale of Map. |
2 |
6- |
Managing Layers in Arc
Map. |
2 |
7- |
Coordinates System. |
2 |
8- |
Query (Identify & find),
Analyze (Proximity, Overlay, Network), Hyperlink. |
4 |
9- |
Polynomial Rectification. |
2 |
10- |
Arc Catalog applications. |
2 |
11- |
Maps Creation (Shape
File). |
2 |
12- |
Maps Creation, Geo Data
Base (GDB). |
2 |
13- |
Data base Creation &
Managing with Table. |
2 |
14- |
Graphs Creation, Reports. |
2 |
15- |
Layout, Grids |
2 |
16- |
Digital Image,
preprocessing. |
2 |
17- |
ERDAS imagine, Viewer,
displaying Image. |
2 |
18- |
Subset Image, Export &
Import. |
2 |
19- |
Enhancement (Spatial,
Radiometric, Spectral). |
2 |
20- |
Spatial Enhancement
(Resolution Merge). |
2 |
21- |
Image Enhancement &
Filters. |
2 |
22- |
Unsupervised
Classification. |
2 |
24- |
Supervised
Classification. |
2 |
25- |
Accuracy Assessment. |
2 |
26- |
Layer Stack. |
2 |
27- |
Global positioning System
(GPS). |
4 |
28- |
Ground Penetration Radar
(GPR). |
4 |
|
|
|
|
B.E. 4304
Theory of Structures
|
Theory:
3hrs./ Week
Tutorial: 1hr./ Week |
1- Stability and
Determinacy of Structures. |
8 |
2- Frames and Trusses. |
12 |
3- Influence Lines:
Definition & use,
Beams, Trusses (Statically Determinate). |
8 |
4- Moving load:
Max. moments and
Shears, Max. forces in truss members. |
6 |
5- Use of virtual work
(Unit load) method for deflection of statically
determinate structures. |
12 |
6- Approximate
analysis of indeterminate structures. |
8 |
7- Force method for
the analysis of statically indeterminate structures. |
8 |
8- Method of least
work for the analysis of statically indeterminate
structures. |
6 |
9- Displacement method
(Slope-deflection) for the analysis of statically
indeterminate structures. |
14 |
10- Moment
distribution for beams and frames. |
8 |
|
|
|
B.E. 4305
Highway Design
|
Theory: 2hrs./ Week
Practical: 1hr./ Week
Tutorial: 1hr./ Week |
1- Selection of route
location of highways. |
6 |
2- Cut and fill works,
costs and economics |
14 |
3- Cross section
characteristics highways. |
6 |
4- Design of
horizontal alignment. |
6 |
5- Design of vertical
alignment. |
6 |
6- Drainage systems in
highways. |
8 |
7- Highway lighting. |
6 |
8- Highway furniture. |
8 |
|
|
|
B.E. 4306 Pavement Design
|
Theory: 2hrs./ Week
Practical: 1hr./ Week |
1- Subgrade soil and
its stabilization. |
6 |
2- Sub-base layer. |
6 |
3- Asphalt materials. |
6 |
4- Asphalt mixes. |
6 |
5- Production of
asphalt mixes. |
6 |
6- Difference between
highway and airports. |
2 |
7- Flexible pavement,
distribution of stresses, equivalent load. |
4 |
8- Rigid pavement,
distribution of stresses, equivalent load. |
4 |
9- Design of flexible
pavement for highways. |
6 |
10- Design of flexible
pavement for airports. |
4 |
11- Design of rigid
pavement for highways. |
6 |
12- Design of rigid
pavement for airports. |
4 |
Laboratory
Tests
|
1- Penetration test. |
5- Viscosity test. |
2- Ductility test. |
6- Loss on heating
test. |
3- Softening point
test. |
7- C.B.R. test. |
4- Flash point test. |
8- Marshall test. |
|
|
|
|
B.E. 4307 Railway
Engineering
|
Theory: 2
hrs./ Week
|
Site and Operation
1- Introduction to
manufacture of railways. |
2 |
2- Railway traffic. |
2 |
3- Operational energy. |
4 |
4- Slope and
deflection. |
4 |
5- Acceleration and
deceleration. |
4 |
6- Speed. |
4 |
7- Problems in grades. |
6 |
8- Setting out
operation. |
4 |
Construction and
Maintenance
9- Wagon (loads and
analysis). |
2 |
10- Design and
construction of sub-ballast layer. |
4 |
11- Construction cost
of sub-ballast layer. |
2 |
12- Stability of
sub-ballast layer. |
2 |
13- Drainage systems. |
4 |
14- Ballast layer. |
2 |
15- Joints. |
6 |
16- Geometric design
of railway lines. |
2 |
17- Intersections. |
6 |
|
|
|
B.E. 4308 Reinforced
Concrete Design
|
Theory: 2hr./ Week
Tutorial: 1hr./ Week |
1- Introduction to
reinforced concrete. |
4 |
2- Beam analysis by
working stress method. |
4 |
3- Strength method for
analysis and design. |
12 |
4- Design of
continuous beams. |
6 |
5- Deflections in
beams. |
4 |
6- Shear design. |
8 |
7- Design for shear
and torsion. |
6 |
8- Methods of
coefficients for two-way slabs. |
8 |
9- Splices and
anchorage of reinforcement. |
4 |
10- Introduction to
concentrically loaded columns. |
4 |
|
|
|
B.E. 4309
Traffic Engineering
|
Theory: 1hr./ Week
Tutorial: 1hr./ Week |
1- Principles of
traffic, traffic volume-speed-density relationship. |
5 |
2- Traffic growth. |
2 |
3- Traffic capacity. |
3 |
4- Characteristics of
traffic, traffic components. |
3 |
5- At-grade
intersections. |
2 |
6- Interchanges. |
3 |
7- Traffic analysis,
traffic signs. |
5 |
8- Design of
signalized intersections. |
5 |
9- Off street parking,
on street parking. |
2 |
|
|
|
Fourth Year
Subject
|
Hrs./week |
Units |
Theo. |
Prac. |
Tut. |
B.E.4401
|
Management and
Engineering Economy |
3 |
1 |
1 |
7 |
B.E.4402
|
Earth Structures |
3 |
- |
- |
6 |
B.E.4403
|
Design of Concrete
Bridges |
3 |
- |
1 |
6 |
B.E.4404
|
Design of Steel Bridges
|
2 |
- |
1 |
4 |
B.E.4405
|
Highway Specifications
and Maintenance |
2 |
- |
- |
4 |
B.E.4406
|
Computer Applications |
1 |
2 |
- |
4 |
B.E.4407
|
Foundation Engineering
|
2 |
- |
1 |
4 |
B.E.4408
|
Airport Engineering |
1 |
- |
1 |
2 |
B.E.4409
|
Graduation Project |
- |
4 |
- |
4 |
Total
|
17 |
7 |
5 |
41 |
29 |
B.E. 4401 Management and
Engineering Economy
|
Theory: 3hrs./Week
Practical: 1hr./Week
Tutorial: 1hr./Week |
1- Project management
objectives. |
3 |
2- Responsibilities
for quantitative survey. |
3 |
3- Quantity surveying
for civil engineering. |
8 |
4- Quantity surveying
for building works. |
6 |
5- Cost planning &
approximate estimation. |
6 |
6- Work pricing. |
6 |
7- Contracting &
bidding. |
4 |
8- General contracting
rules. |
6 |
9- Payment on works I. |
4 |
10- Payment on works
II. |
4 |
11- Specifications of
works. |
3 |
12- Planning methods &
scheduling. |
11 |
13- Time & cost
relation. |
6 |
14- Engineering
economic principles and objectives. |
3 |
15- Economic
alternating comparison. |
11 |
16- Economic
feasibility study. |
6 |
|
|
|
B.E. 4402 Earth
Structures
|
Theory: 3hrs./ Week
|
Part I Soil
Improvement
|
A- Temporary soil
improvement
1- Water table lowering
a- Sumps and ditches
b- Sheeting and open
pumping
c-Vacuum dewatering
system
d- Drainage by
electro-osmosis
e- Well point system
2- Ground freezing
3- Electro – osmosis |
9
|
B- Permanent soil
improvement
1- Without adding any
material
a- Heavy tamping
b- Compaction by
explosives
c- Deep compaction using
vibratory probes
d- Thermal treatments
e- Surface stabilization
by compaction
2- Soil stabilization by
admixtures
a- Lime stabilization
b- Cement stabilization
c- Asphalt stabilization |
18
|
C- Deep stabilization by
admixtures
1- Soil grouting
2- Soil replacement
3- Creation of columns
4- Earth reinforcement
5- Preloading and sand
drains |
18
|
Part II Stability of
Slopes
|
1- Stability calculation
for granular soils
2- Stability calculation
for cohesive soils
3-Total stress analysis
for determination of factor of safety
4- Taylor's Stability
number
5-Effective stress
analysis for determination of factor of safety
a- The conventional
method
b- The Simplified method
c- The Rigorous method |
18
|
Part III Earth
Pressures and Retaining Walls
|
1- Types of lateral earth
pressure
a- Earth pressure at rest
b- Active earth pressure
c- Passive earth pressure
2- Rainkine's theory of
earth pressure
3- Coulomb's theory of
earth pressure
4- The choice of backfill
material
5- Backfill drainage
6- Filter design criteria
7- Stability of retaining
walls
8- Proportioning design
of retaining walls
|
12
|
Part IV Sheet Piled
Walls |
1- Cantilever sheet
piles
2- Anchored sheet piles
|
9 |
Part V Braced Cuts |
-Design of various
components of braced cuts |
6 |
|
|
|
B.E. 4403 Design
of Concrete Bridges
|
Theory:
3hrs./Week
Tutorial: 1hr./
Week
|
1- Introduction to
types of bridges, spans, loading, seismic and wind
forces.
|
4 |
2- Design of one way
slab bridges.
|
6 |
3- Deck girder
design.
|
8 |
4- Introduction to
cable suspension bridges.
|
4 |
5- Continuous
bridges: Spans, analysis of continuous bridges,
girders with constant and variable sections, method
of analysis, influence lines, design procedure.
|
12 |
6- Arch bridges:
Introduction, arches with three hinges supports,
arches with two hinges supports, analysis of arches,
influence lines for lateral forces, moments.
|
12 |
7- Prestressed
concrete bridges: Methods for prestressing, loss of
prestressing.
|
24 |
8- Concrete bridges.
|
8 |
9- Sub-structures of
bridges: Sub-structures, piers, design of piers,
bridge shoulders, design of bridge shoulders.
|
12 |
|
|
|
B.E. 4404 Design
of Steel Bridges
|
Theory: 2hrs./ Week
Tutorial: 1hr./ Week
|
1- Historical
background: Types of steel bridges, components of
bridges, bridge loadings, analysis and design of
bridges, Design criteria.
|
6 |
2- Tension members:
Types of tension members.
|
4 |
3- Beams: Flexural
stresses, shear stresses, buckling, deflection,
detailing.
|
8 |
4- Plate girders:
Introduction, flexural stresses, shear stresses,
buckling, deflection.
|
6 |
5- Compression
members: Effective length, buckling, allowable
stresses, column base.
|
6 |
6- Compression
members of steel structures equilibrium: Theory of
structures, buckling of elastic members, effective
length, compression members in steel structures.
|
6 |
7- Combined flexural
and axial stresses.
|
4 |
8- Welding: Welding
process, types of welds, welding requirements.
|
4 |
9- Fatigue: Factors
affecting fatigue, fatigue tests.
|
4 |
10- Local buckling:
Axial compression of plates, design requirements.
|
4 |
11- Bolted and
riveted connections.
|
4 |
12- Welded
connections.
|
4 |
|
|
|
B.E. 4405 Highway
Specifications and Maintenance
|
Theory: 2hrs./
Week
|
1- General
specifications.
|
2
|
2- Reinforced
concrete pipe culverts.
|
1
|
3- Un-reinforced
concrete pipe culverts.
|
1
|
4- Steel culverts.
|
1
|
5- Pipes and
drainage.
|
2
|
6- Earth works.
|
2
|
7- Selection of
subbase materials.
|
2
|
8- Lime stabilization
of subbase layers.
|
2
|
9- Base course layer:
Subgrades in calcareous soils, base course from
subbase soils, compacting base course using
vibratory compactors.
|
3
|
10- Stabilization
using bituminous materials.
|
2
|
11- Surface asphalt
layers: Prime coat, tack coat.
|
2
|
12- Hot asphalt
concrete pavement layer.
|
2
|
13- Portland cement
concrete pavement.
|
2
|
14- Curbstone.
|
2
|
15- Obstacles.
|
1
|
16- Highway green
areas.
|
1
|
17- Traffic signals,
highway and bridge furniture.
|
2
|
18- Pile foundations
for bridges.
|
3
|
19- Large diameter
piles.
|
3
|
20- Scaffold for
concrete works.
|
3
|
21- Reinforcement for
bridges.
|
3
|
22- Reinforced
concrete for bridges
|
3
|
23- Prestressed
Bridges.
|
3
|
24- Reinforcement
works.
|
2
|
25- Water protection
works for bridges.
|
2
|
26- Protection of
steel work from corrosion.
|
2
|
27- Bridge abutments.
|
2
|
28- Guard rails.
|
2
|
29- Joint movements.
|
2
|
|
|
|
B.E. 4406
Computer Applications
|
Theory: 1hr./
Week
Practical: 2hrs./
Week
|
Application By
STAAD III Software
|
1- Introduction to
STAAD III
|
3
|
2- Geometry of
structures
|
2
|
3- Member properties
|
2
|
4- Material
properties
|
2
|
5- Boundary
conditions
|
4
|
6- Application of
loads
|
2
|
7- Methods of
analysis
|
6
|
8- Design of
structures
|
4
|
9- Applications to 3
degree of freedom structures
|
5
|
|
|
|
B.E. 4407 Foundation
Engineering
|
Theory: 2 hrs./ Week
Tutorial: 1 hr./
Week |
1- Soil
investigation:
Determination of
spacing, No. of bore holes, depth of bore holes,
type and methods of drilling, sampling and samples,
in situ tests, geophysical exploration, report
writing |
6 |
2- Bearing
capacity of Shallow foundation:
Types of shear
failure, Determination of ultimate bearing capacity
of soil, eccentrically loaded foundations, bearing
capacity of footing on layered soils, bearing
capacity of footing on slopes, determination of
bearing capacity from field tests. |
14 |
3- Settlements of
shallow foundations:
Immediate or
elastic settlements, consolidation settlements,
secondary settlements, prediction of settlement for
cohesionless soils, elastic settlements of
eccentrically loaded foundations, allowable
settlements. |
6 |
4- Foundations on
difficult soils:
Collapsing soils,
expansive soils. |
2 |
5- Structural
design and determination of dimensions of footings:
Separated
footings, combined foundations, rectangular
foundations, trapezoidal foundations, strap
foundations and raft foundations. |
8 |
6- Pile
foundations:
Pile
classification, pile capacity in cohesive soils,
pile capacity in cohesionless soils, pile capacity
for c-f
soils, pile capacity of tension piles, determination
of pile capacity from in situ tests, negative skin
friction of piles.
-Pile groups:
Group action,
efficiency of group piles, ultimate bearing capacity
of group piles, pile groups subjected to moments,
settlement of pile groups.
-
pile
dynamic formulae
-
pile
load tests |
16 |
7- Earth pressures
and retaining walls:
Types of lateral
earth pressures, Rankine theory of earth pressures,
Coulomb’s theory of earth pressures.
-
Stability of retaining walls
-
Sheet pile walls:
Cantilever sheet
pile walls and anchored sheet pile walls
|
8 |
|
|
|
B.E. 4408 Airport
Engineering
|
Theory: 1hr./
Week
Tutorial: 1hr./
Week |
1- Introduction to
airport engineering.
|
1
|
2- Characteristics of
airplanes.
|
3
|
3- Fundamental design
of airports.
|
4
|
4- Geometric design
of runway and taxiway.
|
4
|
5- Structural design
of pavement layers.
|
5
|
6- Water drainage in
airports.
|
4
|
7- Landing design.
|
3
|
8- Signals and signs.
|
2
|
9- Runway lighting.
|
2
|
10- Environmental
effect of airports.
|
2
|
|
|
|
|