ART 102 Presentation for all the student of ART 103 course .pptx
1. IUBAT - International University of Business Agriculture and Technology
Phone: (88 02) 55091801-5, Cell: +88 01714014933, Fax: (880-2) 5895 2625, www.iubat.edu, info@iubat.edu
Founded 1991 by Md. Alimullah Miyan
4 Embankment Drive Road, Sector 10, Uttara Model Town, Dhaka 1230, Bangladesh
Department: BSCE
Subject: Educational Planning
Subject Code: ART-102
Section: J
Education
in
Civil Engineering
Group 2
1
2. 2
Presenter Information
SN Name Page
1 Md. Abu Syeed 1 to 9
2 Ridoy Rana 15 to 23
3 Md. Delowar Hossen Sarkar 9 to 11
4 Md. Borkat Ullah 24 to 27
5 Jamiul Islam 28 to 31
6 Saimum Hasan Anik 32 to 44
3. 3
Outline of this Presentation
• Introduction
• Overview of the Materials
▪ Transportation Engineering
▪ Coastal Engineering
▪ Structural Engineering
▪ Environmental Engineering
▪ Geotechnical Engineering
▪ Water Resources Engineering
• Analysis
• Conclusion
4. 4
Introduction
Civil engineering is a professional engineering discipline that deals with
the design, construction, and maintenance of the physical and naturally
built environment, including public works such as roads, bridges, canals,
dams, airports, sewage systems, pipelines, structural components of
buildings, and railways.
Civil Engineering Mind
6. Transportation as a System
6
Transportation engineering or transport engineering is the application of
technology and scientific principles to the planning, functional design,
operation and management of facilities for any mode of transportation in
order to provide for the safe, efficient, rapid, comfortable, convenient,
economical, and environmentally compatible movement of people and
goods transport.
Roundabout Transport
11. What is Costal Engineering?
11
Coastal engineering is a branch of civil engineering concerned
with the specific demands posed by constructing at or near
the coast, as well as the development of the coast itself.
Ilfracombe, North Devon Coast, England
16. Engineering Structure
16
A structure is an arrangement and organization
of interrelated elements in a material object
or system, or the object or system so organized.
The Eiffel Tower in Paris is a historical
achievement of structural engineering.
Eiffel Tower
Structural engineering depends upon a detailed
knowledge of applied mechanics, materials
science, and applied mathematics to
understand and predict how structures support
and resist self-weight and imposed loads.
17. Structural Engineering Theory
17
To apply the knowledge
successfully a structural engineer
generally requires detailed
knowledge of relevant empirical
& theoretical design codes, the
techniques of structural analysis,
as well as some knowledge of
the corrosion resistance of the
materials and structures,
especially when those structures
are exposed to the external
environment. Shear Stress
18. Building Structures
18
Structural building engineering is primarily driven by the creative
manipulation of materials and forms and the underlying mathematical and
scientific ideas to achieve an end that fulfills its functional requirements
and is structurally safe when subjected to all the loads it could reasonably
be expected to experience.
• Earthquake engineering
• Facade engineering
• Fire engineering
• Roof engineering
• Tower engineering
• Wind engineering
Opera House, Sydney
19. Mechanical structures
19
• Boilers and pressure vessels
• Coachworks and carriages
• Cranes
• Elevators
• Escalators
• Marine vessels and hulls
20. Aerospace structures
20
Aerospace structure types include launch vehicles, (Atlas, Delta,
Titan), missiles (ALCM, Harpoon), Hypersonic vehicles (Space
Shuttle), military aircraft (F-16, F-18) and commercial aircraft (Boeing 777,
MD-11). Aerospace structures typically consist of thin plates with stiffeners
for the external surfaces, bulkheads, and frames to support the shape and
fasteners such as welds, rivets, screws, and bolts to hold the components
together.
Airbus A380
21. Nanoscale Structures
21
Missile
A nanostructure is an object of
intermediate size between
molecular and microscopic
(micrometer-sized) structures.
In describing nanostructures it
is necessary to differentiate
between the number of
dimensions on the nanoscale.
33. Water Resource
33
Water and civil engineering is a multidisciplinary field focused
on the sustainable management of water resources, including
the design and construction of infrastructure such as dams,
bridges, and water treatment facilities to ensure safe and
efficient water supply and sanitation for communities and
ecosystems.
34. Erosion Control
34
Water plays a critical
role in managing
erosion and sediment
control at construction
sites.
Proper erosion control
measures are essential
to prevent soil loss and
protect the
environment.
Drought
35. 35
Excavation and Dredging
Water is necessary for
excavating foundations
and for dredging,
especially in areas near
water bodies or for
constructing ports and
harbors.
Excavation
36. Foundation Design
36
Understanding
groundwater conditions is
crucial in foundation
design.
Civil engineers need to
consider factors like the
water table level when
designing foundations to
prevent issues like
settlement and buoyancy.
37. Hydroelectric Power
37
Civil engineers design and
construct hydroelectric power
plants to harness the energy
of water flow, providing
renewable and sustainable
energy sources.
38. Transportation Infrastructure
38
Water bodies can present
significant challenges for
transportation
infrastructure.
Engineers design bridges,
tunnels, and culverts to
safely cross rivers, lakes, and
other water bodies.
39. Water Supply Systems
39
Civil engineers are
responsible for
designing and
maintaining water supply
systems to ensure that
clean and safe drinking
water is available to
communities.
40. Environmental Sustainability
40
In an era of increasing focus on
sustainability, civil engineers
work on projects that manage
water resources efficiently and
promote water conservation.
42. Conclusion
42
Civil engineering systems is a discipline that promotes the use of
systems thinking to manage complexity and change in civil
engineering within its wider public context. It posits that the
proper development of civil engineering infrastructure requires
a holistic, coherent understanding of the relationships between all
of the important factors that contribute to successful projects
while at the same time emphasizing the importance of attention
to technical detail. Its purpose is to help integrate the entire civil
engineering project life cycle from conception, through planning,
designing, making, operating to decommissioning.