Introduction to Structural Concrete Design PDF

Summary

This document provides an introduction to structural concrete design, covering the design process, considerations, and classification of structural concrete. It also includes learning outcomes, a reading guide, and a lecture outline. The document is aimed at an undergraduate level.

Full Transcript

Introduction to Structural
Concrete Design
CEPRCD30 (Principles of Reinforced Concrete)

Jerome Z. Tadiosa, CE, MSc
Assistant Professor 2, Civil Engineering
College of Engineering
National University – Manila
Intended Learning Outcomes
Describe the structural design process and considerations.
Explain the description, development, and classification of
structural concrete.
Enumerate and describe the design philosophies in structural
concrete design, and the relevant codes and standards used.
Enumerate and describe the materials used in structural concrete
construction.
Reading Guide
Read the following book chapters and other references for better
understanding of lecture:
Chapters 1-3, Wight (2016)
Chapter 1, McCormac & Brown (2016)
Sections 1.1-1.2, Chapter 1, Salmon et.al. (2009)
Lecture Outline
1. Introduction to structural design process
2. Introduction to structural concrete design
3. Materials in structural concrete design
Introduction to Structural Design
Structural Design
“May be defined as a mixture of art and science, combining the
experienced engineer’s intuitive feeling for the behavior of
structures, with a sound knowledge of basic engineering
principles, to produce a safe, economical structure that will serve
its intended purpose.” (Salmon et.al., 2009)
A properly-designed structure should satisfy four criteria:
Appropriateness: functionality and aesthetics
Economy: optimal benefit-cost ratio, preferably minimum cost
Structural adequacy: strength and serviceability requirements
Maintainability: minimum maintenance cost and time
General Design Process
Major phases of general design process include the following:
Definition of client’s needs and priorities: function, aesthetic preferences,
budget
Development of project concept: schematics, preliminary framework,
materials
Design of individual systems: structural analysis and design, utilities
and other systems
Structural design is sequential and iterative in nature.
It follows a series of steps without skipping.
It involves decisions that may result to a series of repeats of previous
steps.
Structural Design Process
1. Planning: setting and finalizing project details
2. Preliminary structural configuration: initial arrangement of
structural members
3. Establishment of loads: applying loads on structure model
depending on material, function, and site conditions
4. Preliminary member selection: initial sizing of structural
members
5. Structural analysis: modeling and analyzing structure to
determine forces and deformations
Structural Design Process
6. Evaluation: checking individual members against strength and
serviceability requirements, as well as client specifications
7. Redesign: repetition of previous steps depending on the results
of the evaluation
8. Final decision: determining whether the latest iteration of design
is optimum
Structural Concrete
Defined as “plain or reinforced concrete in a member that is part
of a structural system required to transfer loads along a load path
to the ground” (ACI, 2013)
Concrete is a “mixture of hydraulic cement, aggregates, and
water, with or without admixtures, fibers, or other cementitious
materials”. (ACI, 2013)
Plain concrete is a “structural concrete with no reinforcement or
with less reinforcement than the minimum amount specified for
reinforced concrete in the applicable building code”. (ACI, 2013)
Introduction to Structural
Concrete Design
Structural Concrete
Reinforced concrete is a “structural concrete reinforced with no
less than the minimum amount of prestressing steel or non-
prestressed reinforcement as specified in the applicable building
code”. (ACI, 2013)
Reinforced concrete may be classified as either steel-reinforced
concrete (using rebars) or prestressed concrete (using tendons).
This course will focus mainly on steel-reinforced concrete, with a
brief overview on prestressed concrete.
Advantages of Structural Concrete
High compressive strength
Great resistance to fire and water
Rigidity
Low maintenance
Long service life
Most economical material for substructures and floor slabs
Moldability
Cheap cost of components
Lower required labor skill requirement
Disadvantages of Structural Concrete
Low tensile strength
Formworks requirement
Low strength-to-weight ratio
Low strength-to-volume ratio
Variation of properties due to proportioning and mixing (quality
consistency issue)
Historical Background of Concrete
Lime mortar was first used in the Minoan civilization (Crete, ~2000
B.C.).
In the 3rd century B.C., Romans mixed lime mortar with volcanic
ash (pozzolana) to create stronger, water-resistant mortar.
John Smeaton (before 1800) designed the Eddystone Lighthouse
using Roman cement but also experimented with a mix of
limestone and clay to create water-resistant cement.
Joseph Aspdin (1824) created Portland cement by heating ground
limestone and clay, named after Portland stone, a high-grade
limestone.
Historical Background of Concrete
Accidental overheating of the cement mixture produced clinker,
later found to make stronger cement (discovered by I.C. Johnson
in 1845).
Some personalities involved in the development of structural
concrete design include:
W. B. Wilkinson (1854): Patented a reinforced concrete floor system using
hollow plaster domes and steel mine-hoist ropes as reinforcement.
Joseph Lambot (France, 1848): Built a reinforced concrete rowboat and
patented his concept in 1855, showing reinforced beams and columns
with iron bars.
Historical Background of Concrete
Some personalities involved in the development of structural
concrete design include:
Thaddeus Hyatt (U.S., 1850’s): Experimented with reinforced concrete
beams using longitudinal bars and stirrups for shear, though his work
remained unknown until 1877.
Joseph Monier (France, 1867): Patented reinforced concrete for tubs,
followed by patents for pipes, tanks, plates, bridges, and stairs between
1868 and 1875.
W. E. Ward (U.S., 1875): Built the first reinforced concrete house in the
United States on Long Island.
E. L. Ransome (California, 1870’s-1880’s): Patented a twisted steel
reinforcing bar in 1884, developed his own design procedures, and built
significant structures using reinforced concrete.
Historical Background of Concrete
Some personalities involved in the development of structural
concrete design include:
Coignet and de Tedeskko (1894): Extended Koenen's theories to develop
the working-stress design method for reinforced concrete flexure, widely
used from 1900 to 1950.
E. Freyssinet (1928): Pioneered the use of high-strength steel wire for
prestressing, solving the problem of concrete creep, and developed
anchorages and designs for bridges and structures.
A series of patents shaped the science of reinforced concrete,
with an English textbook in 1904 listing 43 patented systems
across countries between 1875 and 1900.
Limit States
Limit states are the conditions of a structure or a structural
member when it becomes unfit for its intended use.
Limit states are classified into three basic groups:
Strength limit states: involve structural failure or collapse of a part or
most of a structure (e.g. loss of equilibrium, failure, progressive collapse,
formation of plastic mechanism, instability, fatigue)
Serviceability limit states: involve disruption of functional use of a
structure; does not necessarily be followed by collapse (e.g. excessive
deformations, excessive cracking, undesirable vibrations)
Special limit states: involve damage or failure due to abnormal conditions
(e.g. extreme calamities, fire, corrosion effects)
Limit States
Limit states design involves the following:
Identification of all possible failure modes or limit states
Determination of acceptable levels of safety for each limit state
Structural design considering significant limit states
For structural concrete, limit states design is done by using the
(ultimate) strength design method (USD).
It is a “design method that requires service loads to be multiplied by load
factors and computed nominal strengths to be multiplied by strength
reduction factors”. (ACI, 2013)
Strength Design Method
The basic criterion for strength requirement for structural design is
that the capacity (or resistance) of a member should be greater
than or equal to the demand (or load effects) placed on the said
member, i.e. capacity ≥ demand.
For structural concrete design using USD:

𝜙𝑅𝑛 ≥ 𝑄𝑢 = ෍ 𝛾𝑖 𝑄𝑖

Φ: strength reduction factor
Rn: nominal member strength
Qu: total factored load
γi, Qi: load factor γi for ith type of load Qi
USD Load
Combinations
(Art. 203.3, Section 203, Chapter
2, 2015 NSCP Vol. 1)

22
Service Load
Combinations
(Art. 203.4, Section 203, Chapter
2, 2015 NSCP Vol. 1)

23
Structural Safety
Reasons for setting load factors and strength reduction factors:
Variability in strength: differences in material properties and section
dimensions; simplified design assumptions
Variability in loadings: differences in material densities and actual load
intensities while the structure is in use
Consequences of failure: taking account some limit states that may
cause higher potential losses in life and property, depending on how they
happen in structural members
Codes and Standards for Structural Concrete
Some of the codes and standards used in structural concrete
design include:
2015 National Structural Code of the Philippines (NSCP) Vol. 1
Chapter 2: Minimum Design Loads
Chapter 4: Structural Concrete
ACI 318M-14 (Building Code Requirements for Structural Concrete)
ACI 318R-14 (Commentary on Building Code Requirements for Structural
Concrete)
Other ACI codes and standards (some will be introduced throughout the
course)
Design for Economy
Economy is a major goal in structural design, influenced by both
construction costs and financing charges tied to the speed of
construction.
In cast-in-place buildings, floor and roof systems make up about
90% of the total structural cost.
Material costs increase with larger column spacing, but formwork
reuse can reduce costs. Beam, slab, and column sizes should be
chosen to maximize form reuse.
Overcomplicating design to save on materials can increase
forming costs and complexity, leading to higher overall costs.
Design for Economy
Simplified designs reduce the chances of errors, save time, and
result in more economical structures.
Avoid haunched beams and deep spandrel beams, which
complicate form movement. It’s more cost-effective to use
consistent beam depths, even for varying spans.
Standard column sizes should be used for three or four stories (or
the whole building) to simplify formwork. Reinforcement amounts
and concrete strength can vary with load.
Complex reinforcement designs increase labor costs, so it is more
economical to design columns with 1.5-2% reinforcement and
beams with 50-66% of the maximum allowable reinforcement.
Design for Economy
Grade-60 reinforcement is widely used for columns and beams.
For slabs, Grade-40 reinforcement may be advantageous when
controlled by minimum reinforcement ratios, though availability
should be checked.
Concrete strength has little effect on flexural strength of floors, so
using high-strength concrete offers little advantage except in flat-
plate systems where shear capacity is critical.
High-strength concrete is more economical for columns since
their strength is directly related to the concrete strength.
Design for Sustainability
Durability and longevity are key factors for selecting reinforced
concrete in construction, contributing to sustainability.
Reinforced concrete is valued for its aesthetic qualities, versatility,
and both initial and life-cycle economic benefits, including
thermal properties that reduce energy costs.
Sustainable/green construction is seen as a compromise between
economic, social, and environmental factors. Reinforced concrete
fits within this framework.
Design for Sustainability
Aesthetics and occupant comfort: Concrete allows for innovative
architectural designs and improves comfort through thermal
mass, natural lighting, and reduced need for hazardous finishes.
Its durability contributes to long-term sustainability by reducing
renovations and maximizing service life.
Long service life: Reinforced concrete structures are durable, with
a service life typically exceeding 50 years and often over 100
years, reducing long-term costs and resource use.
Reducing carbon footprint: Concrete’s energy-saving properties
during its service life help reduce CO2 emissions, but concerns
remain over cement production.
Materials for Structural Concrete
Construction
Concrete
Concrete is a composite material composed of aggregates
(coarse and fine), cement, water, and admixtures (in some cases).
The aggregates make up the bulk of the weight and the volume of the
concrete.
The mixture of cement and water (cement paste) act as a binding agent to
hold the aggregates together as it hardens.
Admixtures are used to improve some properties of concrete, such as
strength and workability.
Concrete is a brittle material, and in addition, it is strong in
compression but weak in tension. This behavior leads to the use
of reinforcement in concrete.
Concrete
The stress-strain relationship of concrete is nonlinear and appears
to be somewhat ductile as well.
This is due to the development of microcracking within the concrete as it
is subjected to loads. Microcracks are internal cracks with lengths ranging
between 1/8” and 1/2”. Microcracks are classified as either bond cracks
or mortar cracks.
Concrete mix design for general structural purposes are usually
performed using traditional proportions, DPWH-modified
proportions or ACI 211.1-91.
Mechanism of Concrete Failure in
Compression
There are four stages in the microcrack development of concrete
under uniaxial compression loading:
Development of no-load bond cracks due to shrinkage of cement paste
during the hydration process
Development of bond cracks due to stresses in the aggregates exceeding
their strengths as the load stress reaches ~30-40% of the concrete
compressive strength
Development of localized mortar cracks between bond cracks as the load
stress reaches ~50-60% of the concrete compressive strength
Increase in mortar cracks as the load stress goes up to ~75-80% of the
concrete compressive strength
Compressive Strength of Concrete
Concrete sample preparation and testing are performed in
accordance with ASTM C31 (Standard Practice for Making and
Curing Concrete Test Specimens in the Field) and ASTM C39
(Standard Test Method for Compressive Strength of Cylindrical
Concrete Specimens) standards.
Test cylinders are prepared with two possible sizes (H/D = 2.0):
6-in (150 mm) diameter by 12-in (300 mm) height
4-in (100 mm) diameter by 8-in (200 mm) height
Standard concrete age considered as concrete compressive
strength for design purposes is 28 days.
Factors Affecting Concrete Compressive
Strength
Water-cement (w/c) ratio
Lower w/c generally leads to higher compressive strength
Type of cement
Type I (normal): used in ordinary construction
Type II (modified): lower heat of hydration than Type I; used for sites with
moderate sulfate exposure
Type III (high early strength): has higher heat of hydration that Type I
Type IV (low heat): used for mass concrete applications (dams, large walls
etc.); replaced with combination of Types I and II with fly ash
Type V (sulfate resisting): used for underground structural elements
exposed to soils with sulfates
Factors Affecting Concrete Compressive
Strength
Supplementary cementitious materials
Use of other cementitious materials (pozzolans like silica fume and fly
ash, ground granulated blast-furnace slag) reduce heat of reduction and,
in some cases, improve workability.
Aggregate
Concrete strength also depends on the strength, grading, quality, and
toughness of aggregates.
Mixing water
Potable water is required for concrete mixing. Salt water is generally
avoided due to presence of salts that may destroy the microstructure of
the concrete.
Factors Affecting Concrete Compressive
Strength
Curing conditions
Moisture and temperature conditions, as well as curing duration, also
affect the development of concrete strength.
Age of concrete
Concrete strength increases with age, especially within the first seven (7)
days of curing, provided that optimal curing conditions are in place.
Maturity of concrete
Young-age concrete gains strength as long as the concrete maintains a
threshold temperature of ~ -10°C to -12°C.
Rate of loading
Testing at low strain rates results to lower recorded strength; higher strain
rates result to higher recorded strength
Tensile Strength of Concrete
(Modulus of Rupture)
Tensile strength may be determined by
performing materials testing in
accordance with ASTM C78 or ASTM
C496 standard.
ASTM C78: Standard Test Method for
Flexural Strength of Concrete (Using
Simple Beam with Third-Point Loading)
ASTM C496: Standard Test Method for
Splitting Tensile Strength of Cylindrical
Concrete Specimens
Modulus of Rupture
Arts. 419.2.3 & 419.2.4, Sec.
419, Chapter 4, 2015 NSCP
Vol. 1
Factors Affecting Tensile Strength of Concrete
Same factors affect both compressive and tensile strength of
concrete.
Concrete made with crushed rock has higher tensile strength
(~20% higher) than concrete made with rounded gravel.
Tensile strength of concrete develops more quickly than
compressive strength.
Stress-Strain Curve of Concrete in
Compression
Modulus of Elasticity and Poisson’s Ratio of
Concrete
Modulus of Elasticity
Art. 419.2.2, Sec. 419, Chapter
4, 2015 NSCP Vol. 1
Poisson’s Ratio
Varies between 0.11 and 0.21;
may also fall within 0.15 and
0.20
Recommended values based on
various studies are:
0.20 (compression)
0.18 (tension)
0.18-0.20 (tension + compression)
Time-Dependent Volume Changes
Shrinkage
Decrease in the volume of concrete during hardening and drying under
constant temperature.
Types of shrinkage include:
Drying shrinkage: Loss of adsorbed water from gel particles, primarily affected by
relative humidity (highest below 40% RH). Drying shrinkage causes tensile stresses
in the outer concrete surface and compressive stresses in the interior.
Autogenous shrinkage: Occurs without moisture loss, associated with hydration
reactions, more significant in high-performance concretes.
Carbonation shrinkage: Happens in carbon dioxide-rich environments, contributing
significantly to total shrinkage at certain humidity levels (e.g., 50% RH).
Shrinkage has lesser effects in larger members due to higher volume-to-
surface-area ratio.
Time-Dependent Volume Changes
Creep
Permanent deformation of a material due to a combination of sustained
loads and/or elevated temperatures
In concrete, creep strains develop over time if the load remains, due to
the thinning of adsorbed water layers between gel particles. Creep slows
down over time as bonds form between gel particles in their new
positions.
Creep strains develop over two to five years and can be one to three times
the magnitude of the initial elastic strain. Increased creep leads to greater
deflections over time, stress redistribution, and reduced prestressing
forces.
Time-Dependent Volume Changes
Creep
It is influenced by several factors like sustained stress ratio (actual stress
divided by strength), concrete age, humidity, member size, concrete
composition or proportion, temperature, cement type, and water-cement
ratio.
Time-Dependent Volume Changes
Thermal Expansion
Thermal expansion in concrete depends on the composition, moisture
content, and age.
The coefficient of thermal expansion varies based on aggregate type, as
follows:
Siliceous aggregates: 5-7 (10-6)/°F
Limestone or calcareous aggregates: 3.5-5.0 (10-6)/°F
Lightweight concrete: 3.6-6.2 (10-6)/°F
General value: 5.5 (10-6)/°F
The coefficient of thermal expansion may also increase with temperature,
especially at high temperature situations.
Durability Issues in Concrete Structures
Corrosion of steel in the concrete
Involves oxidation process and requires a source of oxygen and moisture
Fresh concrete has a pH of around 13 (alkaline), which helps prevent
corrosion. It starts as soon as the concrete pH drops below 11-12.
Surface rust on steel reinforcement used before concrete pouring helps
improve the bond between concrete and steel. However, as the rust
expands within the reinforcement section, it may cause spalling and
cracking on the concrete member.
Corrosion control measures involve minimum concrete strength and w/c
ratio, minimum clear concrete cover, and limiting chloride content of the
concrete mix.
Epoxy-coated reinforcements may also be used for corrosion control.
Durability Issues in Concrete Structures
Breakdown of structure due to freezing and thawing
When concrete freezes, pressures develop in the water-filled pores,
potentially breaking down the concrete structure.
Air entrainment creates microscopic voids that relieve these pressures,
helping the concrete resist freeze-thaw damage.
Apart from air entrainment, setting minimum w/c ratio, setting minimum
concrete strength, and providing proper drainage may also prevent
adverse effects of freezing and thawing on concrete.
Durability Issues in Concrete Structures
Breakdown of structure due to chemical attack
Some chemical presence and reactions in the site environment may also
affect concrete durability such as sulfate attack, alkali-silica reaction
(ASR), and other chemical attacks.
These may be mitigated by using appropriate cement types and checking
source of aggregates to be used.
Concrete structures that are vulnerable to chemical attack include
pavements, bridge decks, parking garages, water tanks, and foundations.
Extreme Temperature Behavior of Concrete
High Temperature and Fire
Concrete can perform well within a certain time frame during a fire, but
temperature gradients cause surface cracks and spalling. Spalling may
get worse when the surface is suddenly cooled.
Modulus of elasticity and strength of concrete decrease with increase in
temperature.
Aggregate type used in concrete mix may also affect its temperature-
dependent behavior.
Early-age concrete is more susceptible to adverse impacts of fire,
particularly with relation to its tensile strength.
Concrete changes color when heated; pink means damaged, gray means
severely damaged, and damaged concrete beyond gray must be removed
and replaced.
Extreme Temperature Behavior of Concrete
Very Cold Temperatures
Concrete strength increases with decrease in temperature, esp. in moist
concrete without frozen water.
Subfreezing temperatures significantly increase compressive strength,
tensile strength, and modulus of elasticity of moist concrete.
Dry concrete is less affected by low temperatures.
Steel Reinforcement
Defined as “bars, wires, strands, fibers, or other slender elements
that are embedded in a matrix such that they act together to resist
forces” (ACI, 2013)
Commonly used non-prestressed reinforcement types for
concrete include hot-rolled deformed bars and welded wire fabric.
For prestressed concrete, steel tendons are used.
Recent developments include use of other types, especially fiber
reinforcements.
Hot-Rolled Deformed Bars
Steel bars with lugs or deformations rolled into the surface to
improve bond and anchorage into concrete
May be classified depending on the governing ASTM specification
at which they are produced
ASTM A615 (Standard Specification for Deformed and Plain Carbon-Steel
Bars for Concrete Reinforcement)
ASTM A706 (Standard Specification for Low-Alloy Steel Deformed and
Plain Bars for Concrete Reinforcement)
ASTM A996 (Standard Specification for Rail-Steel and Axle-Steel
Deformed Bars for Concrete Reinforcement)
Hot-Rolled Deformed Bars
Hot-Rolled Deformed Bars
Bars are available in different strength grades (Grade 33/230,
Grade 40/300, Grade 60/420, Grade 75/520). The grade number
signifies the rated yield strength of the bar in ksi/MPa.
Grade 40 & 60 are the most commonly used rebar grades in structures.
Grade 75 may be used for large structural members.
Grade 33 is commonly available in the provinces and only recommended
for small or non-critical structures.
Bars are also available in different diameters or sizes.
Hot-Rolled Deformed Bars (Appendix A, Chapter 4, 2015
NSCP Vol. 1)
Hot-Rolled Deformed Bars
Stress-Strain Relationship
Modulus of Elasticity: 200000
MPa (29000 ksi)
Yield Strength: varies with
rebar grade
ASTM specification require
that the ratio of ultimate
tensile strength to yield
strength for weldable bars is
at least 1.25.
In structural design, the
relationship is assumed to be
an idealized elastoplastic.
Hot-Rolled Deformed Bars
Fatigue Strength
Hot-Rolled Deformed Bars
Strength at High
Temperatures
Both yield and ultimate
strength decrease as
temperature decreases,
starting at ~850°F.
Compatibility of Concrete and Steel
Concrete and steel reinforcement work together since concrete
can withstand compressive stresses while steel reinforcement
can deal with tensile stresses, provided that there is adequate
bond between them.
Moreover, concrete provides protection of steel reinforcement
against corrosion and fire, and they also respond to thermal
expansion similarly.
References
American Concrete Institute. (2013). ACI CT-13: ACI Concrete
Terminology. USA: American Concrete Institute
Association of Structural Engineers of the Philippines. (2016). National
Structural Code of the Philippines 2015 Volume 1: Buildings, Towers,
and Other Vertical Structures (7th ed.). Quezon City, Philippines:
Association of Structural Engineers of the Philippines
McCormac, J. C. & Brown, R. H. (2016). Design of Reinforced Concrete
(ACI 318-14 Code Edition, 10th ed.). USA: John Wiley & Sons, Inc.
Salmon, C. et.al. (2009). Steel Structures Design and Behavior:
Emphasizing Load and Resistance Factor Design (5th ed.). USA:
Pearson Prentice Hall
Wight, J. K. (2016). Reinforced Concrete: Mechanics and Design (7th
ed.). USA: Pearson Education, Inc.
References
Sivakugan, N. et.al. (2018). Civil Engineering Materials. USA:
Cengage Learning
Wight, J. K. (2016). Reinforced Concrete: Mechanics and Design
(7th ed.). USA: Pearson Education, Inc.