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**Module 3: Specializations in Civil Engineering** 3.1 Structural
Engineering

Group 3

Ancheta, Arlin

Cañeta, Venice Abegail A.

Dullon, Crisalie

Malay, Zaldy Mapa Jr.

Tombale, Ronato

*Bachelor of Science in Civil Engineering (BSCE) 1-B*

**WHAT IS STRUCTURAL ENGINEERING?**

It is a branch of civil engineering that is concerned with the
structural design of man-made structures.

It is the science and art of planning, designing, and constructing safe
and economical structures. - It involves mathematics, physics, materials
science, and empirical knowledge to evaluate how various materials and
designs perform. These insights are then applied to create structural
systems that are functional, cost-effective, and fit for their intended
purpose while staying within budget constraints.

It focuses more on the framework of structures, and on designing those
structures to withstand the stresses and pressures of their environment.

\- It involves creating designs that ensure structures can withstand
various forces such as gravity, wind, and earthquakes. The ultimate goal
is to ensure safety, functionality, and stability.

→ To better understand structural engineering, note that its principles
were used thousands of years ago in constructing structures like the
pyramids in Egypt and the Acropolis in Greece. In other words, in the
field of structural engineering, you ensure that structures don't fall
down or collapse.

**HOW TO BECOME A STRUCTURAL ENGINEER**

Educational Pathway

1.Bachelor's Degree in Civil Engineering:

The journey begins with obtaining a Bachelor's degree in Civil
Engineering. This undergraduate program provides essential knowledge in
mathematics, physics, and engineering principles. It serves as the
foundation for understanding how structures behave and are constructed.

2.Graduate Studies:

After earning a bachelor's degree, aspiring structural engineers can
further their education by pursuing a Master's degree in Structural
Engineering. These programs, often recognized by the Commission on
Higher Education (CHED), offer specialized courses in structural
analysis, design, and advanced materials. One may become a structural
engineer if they are recognized by one of the following:

Association of Structural Engineers of the Philippines (ASEP)

-ASEP is a prestigious organization for structural engineers in the
Philippines. Being recognized by ASEP is an important milestone in a
structural engineer\'s career. ASEP provides its members with
opportunities for continuing education and access to the latest industry
standards and practices (Quinay and Acosta 2020). Philippine Institute
of Civil Engineers (PICE)

-PICE is another vital organization for civil engineers. It offers
numerous resources for professional development,

networking opportunities, and advocacy for engineers. Recognition by
PICE can significantly enhance an engineer's professional reputation and
credibility (Quinay and Acosta 2020).

Commission on Higher Education (CHED) Recognized University (Graduate
School -- Masters) -Being recognized by CHED is important for a
structural engineer because it establishes credibility and
professionalism by confirming that they meet industry standards. It
ensures regulatory compliance, allowing them to practice legally and
adhere to safety and quality regulations. Additionally, it can enhance
career advancement opportunities, open doors to specialized training,
and provide access to valuable professional networks and resources
(Bukas Blog 2020).

**WHAT DO STRUCTURAL ENGINEERS DO?**

Structural Engineers "design roof framing (beams, rafters, joists,
trusses), floor framing (floor decks, joists, beams, trusses, girders),
as well as arches, columns, braces, frames, foundations and walls,"
according to the National Council of Structural Engineers Association.

In bridges, they design the deck, or riding surface, girders or
stingers, and piers. The materials they use include steel, concrete,
wood, masonry, and aluminum. Engineers design structures that must
resist the forces of gravity, earthquakes, high winds, water, soil
erosion, collisions and blast explosions.

According to STRUCTURAL ENGINEERING: BUILDING STABILITY - Outeng.
(2022), 1. Structural engineers often work alongside civil engineers and
architects as part of a construction team. 2. When building,
particularly bridges, designers must take into account the conditions of
terrain, wind, water and traffic volume. Structural engineers consider
all of these factors and provide technical advice on the project. 3.
Structural engineers become experts at solving problems, meeting
challenges and providing creative solutions.

According to Team, G. C. (n.d.),

Structural Engineers calculate stability, strength and rigidity and make
sure the right materials are used for each project, whether it is a
new-build, conversion or renovation.

**HOW DO STRUCTURAL ENGINEERS ENSURE BUILDING STABILITY?**

According to STRUCTURAL ENGINEERING: BUILDING STABILITY - Outeng.
(2022),

Designing and analysing gravity support and the lateral force
resistance of buildings, bridges, power plants, electrical towers, dams,
and other large structures that are part of our modern life. Gravity
refers to vertical loads and lateral force to horizontal loads. A
structure must be designed so that as a system, it can resist all loads
intended to act upon it. A structural engineer will focus on frameworks,
designing those structures to withstand the stresses

and pressures of their environment and so that they remain safe, stable
and secure throughout their use. Analysing blueprints, maps, reports,
and topographical and geological data; estimating the cost and
quantities of materials, equipment and labour; computing load and grade
requirements, water flow rates, and material stress factors to determine
design specifications; inspecting project sites to monitor progress and
ensure the project is being constructed according to design
specifications; conducting studies of traffic patterns or environmental
conditions to identify potential problems and assess how they will
affect

Designers can help buildings withstand quake shocks by adding a
flexible steel skeleton, or fitting a \'base isolation\' system to
separate the building from its foundations.

**STRUCTURAL ENGINEERING BASICS**

These are the essential information regarding Structural Engineering,
particularly for those individuals who have invested money in a building
or structurebe

1\. Loads

In structural engineering, loads are forces that structures must be
designed to resist. These loads create stresses on the load-bearing
elements of the structure. There are two primary types of loads:
vertical and horizontal.

Vertical Loads: These include the weight of structural materials,
finishes, furniture, people, and environmental factors such as snow or
rain.

Horizontal Loads: These are forces that act horizontally, such as wind
pressure, soil weight against walls, and seismic forces from
earthquakes.

2\. Building Materials

Structures can be constructed using various types of building materials,
each with unique properties, characteristics, and costs. The choice of
material depends on the type, appearance, and budget of the structure.
The most common building materials are wood, reinforced concrete, steel,
and masonry.

2.1. Wood

Wood is a naturally available, economically viable material that is
lightweight and easy to work with. It also provides good insulation,
making it ideal for homes and residential buildings.

Different types of wood have varying strengths and properties,
influencing their suitability for different applications.

A significant drawback of wood is its flammability, which requires
additional fire-proofing measures, which can increase costs.

Wood is most suitable for structures with smaller loads and shorter
spans between load-bearing elements. 2.2. Reinforced Concrete

Reinforced Concrete is a composite material made of concrete and steel
reinforcing (also called rebar). Concrete is strong in compression but
weak in tension, which is why steel rebar is embedded to resist tension
loads.

It is highly versatile and used in a wide range of structures, including
tall multi-story buildings, bridges, roads, and so many other
applications.

Reinforced concrete can be cast on-site or pre-cast in a controlled
environment before installation.

Despite its labor-intensive nature, reinforced concrete is desirable due
to its durability, strength, and excellent fire resistance.

2.3. Steel

Steel is one of the strongest building materials, with exceptional
strength in both tension and compression.

It has a high strength-to-weight ratio, making it ideal for the
structural framework of tall buildings and large industrial facilities.

Structural steel comes in various standard shapes, such as angles, I
beams, and C-channels, which can be welded or bolted together to form
structures that can withstand large forces and deformations.

While steel is relatively expensive, it is quick to install and supports
large loads without occupying a lot of space, which is advantageous for
maximizing usable building space.

2.4. Masonry

Masonry construction involves individual units, such as concrete blocks,
bonded together with mortar. Masonry is strong in compression, making it
suitable for load-bearing walls.

Steel reinforcing can be added to masonry walls to resist tension or
bending due to lateral loads, and grout can be used to increase the
strength of the structure.

Other masonry materials include brick, stone, and glass blocks.

Masonry is durable and easy to construct, but its properties limit its
use in certain applications.

**Stress**

Structural engineers design structures based on the stresses imposed on
load-bearing elements. Stress is determined by the magnitude of the load
and the geometry of the element. Each material has different stress
limits, and understanding these limits is crucial for structural safety.

**Stress** is defined as force applied over an area. A load spread over
a smaller area results in higher stress, while a load spread over a
larger area results in lower stress.

The primary types of stresses that structural engineers design for
include:

Bending, also called flexural stress, arises when a material is
subjected to a bending load or force. This type of stress occurs when
structures or components, such as beams, bridges, and columns, are
subjected to loads that cause them to bend or flex. (McClements &
Lichtig, 2024)

1\. Compression: When an outside force is exerted to compress or squeeze
a thing, (McClements & Lichtig, 2024)

2\. Tension --is a state of stress in which a material pulls apart.
(Tension, 2022)

3\. Torsion, commonly known as the twist force, is a force provided to a
building component or an object that causes one end to twist to the
other end. Hassan, M. (2023)

4\. Shear is a measurement of how easily a force applied causes one plane
in the material to move or deform along another. In real terms, a solid
object's shape is deformed when a shear force is applied, allowing
various material layers to move past one another. (Lichtig, 2024)

5\. Bearing refers to the pressure at which two distinct bodies come into
contact. (JoVE, 2024)

Beams, Joist and Trusses

These are the horizontal members that resist vertical loads on a floor
or roof structure. Beams, joists, and trusses transfer load to the
vertical members of the structure. Joists are often smaller and lighter
than beams. Joists transfer load to larger beams that take load to
vertical columns. Usually, the deeper the beam, joist, or truss, the
longer it can span without deflecting too much or becoming overstressed.
Trusses are an economical option for long spans and are built up of
multiple horizontal, vertical, and diagonal elements that are placed in
either compression or tension. Trusses are often used in the
construction of roofs in homes and in bridges.

Columns

These are the vertical, often slender, members that resist axial loads
from a floor or roof structure. A beam transfers its load into columns,
which take the load down to the foundation. Columns are most often
loaded in compression; unless there is uplift on a structure, they are
loaded in tension.

Load Bearing Walls

This is a wall in a structure that transfers vertical load from a floor
or roof structure down to the foundation or structure below.

Lateral Load Resisting System

This is what stabilizes a building and provides bracing in order to
prevent the structure from collapsing under an earthquake or wind
loading. These could be in the form of steel bracing, solid walls, stair
or elevator shafts, rigid connections, and floor or roof structures.

Connections

This is a critical part of any structure where load is transferred from
one structural element to another. It could be between two structural
elements with the same material or two different materials. Examples of
connections include bolts and welds for steel, nails and screws for
wood, and anchors and studs for concrete and masonry.

Foundations

The loads that a structure is designed to resist need to be transferred
to the ground below the earth's surface. Foundations are the element of
the structure that transfers the building loads to the soil below,
either near the earth's surface or deep into the ground. Footings are an
example of a shallow foundation and are the foundation of choice for
lightly loaded structures such as a house. Piles are examples of deep
foundations and are often the foundation of choice for heavily loaded
structures, such as high-rise buildings.

Building Codes

Building codes are rules and requirements that must be followed when
designing a structure. They will tell you the loads the building should
be designed to resist based on occupancy and geographical location. The
codes are based on testing and experience and are ultimately there to
protect the public and ensure a building is safe for people to occupy.

Structural Drawings

Structural drawings are the blueprints that contractors use to build a
structure. These drawings have information as to what materials are used
and how they come together to form the structure. Structural drawings
often include plans, details, sections, and general notes or
specifications.

Load Transfer and Load Path

Structural engineers need to make sure they design a load path that can
safely transfer the load from its point of application through the
structure all the way to the foundation, where the structure meets the
earth's surface. An example of a load path when designing a house could
be that if snow is applied to a roof, the load will enter the roof
joists or trusses and be transferred to beams, which will transfer loads
to vertical columns or walls that will bear on a foundation that takes
the load into the ground below. Another example would be a gymnast on a
balancing beam. The weight of the gymnast gets transferred into the
balancing beam, then into the supports on each end, and down into the
floor structure. The closer the gymnast is to a support, the higher the
load the support will attract.

Factor of Safety

These are used in the design of structures to account for uncertainty in
the load, strength and quality of material, and workmanship.

**PHASES OF STRUCTURAL ENGINEERING PROJECTS**

1\. Planning Phase. This usually involves the establishment of the
functional requirements of the proposed structure, the general layout
and dimensions of the structure, consideration of the possible types of
structures that may be feasible, and the types of materials to be used.
This phase may also involve

consideration of nonstructural factors, such as aesthetics, the
environmental impact of the structure, and so on.

2\. Preliminary Structural Design. The sizes of various members of the
structural system selected in the planning phase are estimated based on
approximate analysis, past experience, and code requirements. The member
sizes thus selected are used in the next phase to estimate the weight of
the structure.

3\. Estimation of Loads. It involves the determination of all the loads
that can be expected to act on the structure.

4\. Structural Analysis. The values of the loads are used to carry out
analysis of the structure in order to determine the stresses or stress
resultants in the members and the deflections at various points of the
structure.

5\. Safety and Serviceability Checks. The results of the analysis are
used to determine whether or not the structure satisfies the safety and
serviceability requirements of the design codes. If these requirements
are

satisfied, then the design drawings and the construction specifications
are prepared, and the construction phase begins.

6\. Revised Structural Design. If the code requirements are not
satisfied, then the member sizes are revised, and phases 3through 5 are
repeated until all the safety and serviceability requirements are
satisfied.

**REFERENCES**

Noah Moscovitch, M. E.-M. (2019). STRUCTURAL ENGINEERING BASICS. From
https://structuralengineeringbasics.com/wpcontent/uploads/2019/05/Ultimate-Guide-to-Structural-Engineering
Basics-2.pdf

Structural Engineering. (2020, October 20). From
https://www.youtube.com/\@bebangmapagmahal6658 Structural Engineering.
(2020, October 13). From https://www.youtube.com/\@gerrythelion136

TWI Global. (n.d.). Structural engineering FAQs. Retrieved August 12,
2024, from https://www.twi
global.com/technical-knowledge/faqs/structural-engineering

Structural Engineering Basics. (n.d.). What is structural engineering?
Retrieved August 12, 2024, from
https://structuralengineeringbasics.com/what-is-structural-engineering/

(Quinay and Acosta 2020): Structural Engineering
https://ice.upd.edu.ph/structural-engineering/

(Bukas Blog 2020): A Complete Guide On How To Become An Engineer In The

Philippines.https://bukas.ph/blog/a-complete-guide-on-how-to-become-an-engineer-in-the-philippines/

Team, G. C. (n.d.). What does a structural engineer do? (Job
Description). Go Construct.
https://www.goconstruct.org/construction-careers/what-jobs-are-right-for-me/structural
engineer/\#:\~:text=Structural%20engineers%20ensure%20structures%20can,%2Dbuild%2C%20conversion%20or%
20renovation.

STRUCTURAL ENGINEERING: BUILDING STABILITY -- Outeng. (n.d.).

https://www.outeng.co.za/blogs/post/structural-engineering-building-stability

Hassan, M. (2023). Torsional Shear Stress: Overview and Formula.
https://study.com/academy/lesson/torsional shear-stress

formula.html\#:\~:text=The%20torsion%20force%20(sometimes%20referred,the%20object%20or%20structural%20
member.

JoVE. (2024, July 13).

Bearing stress: - JoVE.
https://www.jove.com/science-education/15581/bearing

stress\#:\~:text=Bearing%20stress%20refers%20to%20the,force%20back%20onto%20the%20bolt.
Lichtig, A. (2024, August 8).

Shear Stress: Learn the basics. Xometry.
https://www.xometry.com/resources/materials/shear
stress/\#:\~:text=Shear%20stress%20occurs%20when%20the,acting%20parallel%20to%20the%20surface.
McClements, D., & Lichtig, A. (2024, August 8).

Bending Stress: A Comprehensive guide. Xometry.
https://www.xometry.com/resources/materials/bending
stress/\#:\~:text=Bending%20stress%20is%20a%20fundamental,tensile%20forces%20within%20the%20material.
McClements, D., & Lichtig, A. (2024, August 9).

What to know about Compressive Stress.
https://www.xometry.com/resources/3d-printing/what-is-compressive
stress/Tension. (2022).

Designing Buildings. https://www.designingbuildings.co.uk/wiki/Tension