Chapter 1 - Introduction to Concrete Technology PDF

Summary

This document is an introductory chapter on concrete technology, suitable for civil engineering students. It explains the properties and types of concrete used in construction, with a focus on water-to-cement ratios and different concrete types like normal, high strength, and high-performance concrete.

Full Transcript

Bachelor of civil engineering
(Civil engineering materials)

Prepared by: Dr. Faisal Amsyar
Civil engineering materials
(kns1042)

Chapter 1: Introduction to Concrete Technology
 Group WhatsApp…
First thing first, please join KNS1042 Civil Engineering Materials
Sem 1-2024/2025 group WhatsApp for course updates:
 Course Learning Outcome…
By completing this chapter, students shall be able to:

1.0 Analyze the characteristics of engineering materials used in civil
engineering construction. (Chapter 1, 3, 4)
2.0 Develop concrete mix design based on typical environmental
condition. (Chapter 2) – used for Concrete Lab 1
3.0 Relate and select materials for different applications in civil
engineering works.
Course Learning Outcome…

I will be teaching for
Week 1 – Week 4 on
Concrete Technology:
a) LU1 & LU3 will
combine in week 1
b) LU2 will be in
week 2
c) LU4 will be in
week 3
d) LU5 will be in
week 4
Concrete…
What do you know about concrete?
Concrete…
Or these?
1.1 Introduction to Concrete
Concrete: A composite construction
material composed of cement and
other cementitious materials such
as fly ash and slag cement, aggregate
(generally a coarse aggregate made
of gravels or crushed rocks, plus a
fine aggregate such as sand), water
and sometimes with chemical
admixtures.
1.1 Introduction to Concrete
Simplify: Concrete is widely used
construction material which is a mixture
of cement, aggregates (coarse & fine),
water and admixture.
1.1 Introduction to Concrete
What is mortar?
Mortar: Combination of cement, fine
aggregates and water.
1.1 Introduction to Concrete
What is paste?
Paste: Combination of cement and water
only.
1.1 Introduction to Concrete
Now what is concrete again?
Concrete: Combination of mortar
(cement, fine aggregate and water) with
coarse aggregate.
1.1 Introduction to Concrete
Cement vs. Concrete vs. Mortar
Cement Concrete Mortar
Binding element in both Made of cement, sand and Made of cement, sand and water
concrete and mortar. gravel (coarse) and water. only.
Made of limestone, clay, shells Used for buildings: foundations, Used as the glue to hold bricks,
and silica sand. slabs, patios and masonry. blocks etc. together.
Sets & hardens when combined Most flexible, forming into any Various types available for
with water. mold and rock hard. specific applications.
1.2 Types of Concrete Used in Industry
The requirement of concrete properties is varying depending on the types of
structural elements, geometrical features of the structure, time of
concrete placement and number of skill labourers.
1.2 Types of Concrete Used in Industry
Normal
strength
concrete
High
Precast
strength
concrete
concrete

Types of
Concrete High
Reinforced
performance
concrete
concrete

Light- Self-
weight compacting
concrete concrete
1.2 Types of Concrete Used in Industry
(A) Normal Strength Concrete
Composition: Standard mixture of cement,
aggregate (sand and gravel) with water.
Usage: Used in general construction work,
including residential buildings, pavements and
structure that do not require high strength.
Strength: Typically, around 20 – 40 MPa
(MegaPascal)
1.2 Types of Concrete Used in Industry
(A) Normal Strength Concrete
In Malaysia, the grading of concrete is based
on its compressive strength, similar to
international standards.
The most commonly referred standard for
concrete in Malaysia is the MS 523: Part 1:
2005 (Code of Practice for Structural Use of
Concrete), which align with other standards
such as British Standard (BS 5328) and
Eurocode (EC2).
1.2 Types of Concrete Used in Industry
1.2 Types of Concrete Used in Industry
1.2 Types of Concrete Used in Industry
(B) High Strength Concrete
Composition: Similar to normal
concrete but with a higher ratio of
cement and lower water-to-cement
ratio. Sometimes admixtures are used to
improve performance.
Usage: Suitable for high-rise buildings,
bridges, and structures requiring
superior load-bearing capacity.
Strength: Usually greater than 50 MPa.
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
Definition: The water-cement ratio (w/c ratio)
is the ratio of the weight of water to the weight
of cement used in a concrete mix. It is a key
factor that determines the strength and
workability of concrete.
Range: Common w/c ratios range between 0.40
– 0.60 in general concrete mixes. A lower ratio
means higher strength but lower workability,
and vice versa.
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
Formula:

𝑊𝑒𝑖𝑔ℎ𝑡 𝑜𝑓 𝑊𝑎𝑡𝑒𝑟
𝑊𝑎𝑡𝑒𝑟 − 𝑡𝑜 − 𝐶𝑒𝑚𝑒𝑛𝑡 𝑅𝑎𝑡𝑖𝑜 =
𝑊𝑒𝑖𝑔ℎ𝑡 𝑜𝑓 𝐶𝑒𝑚𝑒𝑛𝑡

*Note: This ratio directly affects the hydration process, which is the chemical
reaction between cement and water gives concrete its strength.
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
Strength: A lower w/c ratio leads to higher
strength because there is less water, leaving
fewer voids after the concrete hardens.
A higher w/c ratio creates weaker concrete
as excess water leaves more voids and
reduces the density of the hardened structure.
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
Workability: A higher ratio
improves workability, making the
concrete easier to mix and pour.
However, it compromises
durability and strength.
A lower ratio results in less
workability, which can make the
concrete hard to handle, but
provides stronger, more
durable.
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
Durability: The right balance
ensures that the concrete can
withstand weathering, corrosion
and wear overtime, reducing
maintenance costs.
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
Concrete mix design: Engineers must
carefully balance water content and
cement to achieve the desired strength
and workability for specific applications.
1.2 Types of Concrete Used in Industry
Water-to-Cement Ratio
1.2 Types of Concrete Used in Industry
(C) High Performance Concrete
Composition: A mixture designed
with specific properties such as high
strength, durability and resistance
to environmental stressors such as
corrosion or freeze-thaw cycles.
Usage: Used in critical infrastructure
like bridges, tunnels, marine
structures and high-rise buildings.
Strength: Usually above 60 MPa.
1.2 Types of Concrete Used in Industry
(D) Self-compacting Concrete
Composition: High-flow concrete that does not require mechanical
vibration to fill in formwork, advantageous of its fluid nature.
Usage: Used in complex structures where access to vibrate the concrete is
limited, such as heavily reinforced elements or narrow spaces.
Strength: Can vary but typically in the range of 30 – 60 MPa.
1.2 Types of Concrete Used in Industry
(E) Light-weight Concrete
Composition: Made using lightweight
aggregates such as expanded clay, shale or
pumice, reducing its density. In lightweight
concrete, they are controlling the density below
1800 kg/m3 (by removing coarse agg.)
Usage: Applied in non-load-bearing structures,
roof decks, and partition walls where reduced
weight is important.
Strength: Lower than normal strength or normal-
weight concrete, typically between 7 – 17 MPa.
1.2 Types of Concrete Used in Industry
1.2 Types of Concrete Used in Industry
(F) Reinforced Concrete
Composition: Concrete that is
strengthened with steel rebar or mesh
to handle tensile stresses better.
Usage: Used in most structural
components like beams, columns, slabs
and foundations in buildings, bridges
and infrastructure.
Strength: Varies depending on design,
but typically used where high tensile
strength is needed.
1.2 Types of Concrete Used in Industry
(G) Precast Concrete
Composition: Concrete components are cast
and cured off-site in a controlled environment
(confined factory), then transported to the
site for assembly.
Usage: Frequently used for repetitive,
modular components such as beams, slabs,
panels and columns in large projects.
Strength: Can be customized to project
needs but generally similar to reinforced
concrete.
1.2 Types of Concrete Used in Industry
(H) Ready-mix Concrete
Composition: Pre-mixed concrete delivered to
the construction site, typically produced in a
batching plant.
Usage: Widely used in large-scale
construction projects for consistency and
quality control, such as highways, commercial
buildings and infrastructure projects.
Strength: Can be altered to the project’s needs,
ranging from normal to high strength.
1.2 Types of Concrete Used in Industry
(I) Green Concrete
Composition: Eco-friendly concrete that uses
recycled materials or supplementary
cementitious materials like fly ash, slag or
silica fume.
Usage: Increasingly used in sustainable
construction practices to reduce the
environmental impact.
Strength: Comparable to conventional
concrete (normal strength concrete),
depending on the mix design.
1.3 Main Components in Concrete
(A) Cement
Cement: A binder, a substance used for
construction that sets, hardens, and adheres to
other materials to bind them together.
Cement: Adhesive substances of all kinds,
but, in a narrower sense, the binding materials
used in building and civil engineering
construction.
1.3 Main Components in Concrete
(A) Cement
Used in construction are
usually inorganic, often
lime or calcium silicate Hydraulic
based, which can be
characterized as non- Cement
hydraulic or hydraulic
respectively, depending Non-hydraulic
on the ability of the
cement to set in the
presence of water.
1.3 Main Components in Concrete
(A) Cement (Non-hydraulic)
Does not set in wet conditions or
under water.
Rather, it sets as it dries and reacts
with carbon dioxide in the air.
It is resistant to attack by chemicals
after setting.
1.3 Main Components in Concrete
(A) Cement (Non-hydraulic)
A less common form of cement is non-hydraulic cement, such as slaked
lime (calcium oxide mixed with water), hardens by carbonation in contact
with carbon dioxide, which is present in the air (~ 412 vol. ppm ≈ 0.04 vol.
%).
First, calcium oxide (lime) is produced from calcium carbonate (limestone
or chalk) by calcination at temperature above 825 °C (1517 °F) for about 10
hours at atmospheric pressure:
1.3 Main Components in Concrete
(A) Cement (Non-hydraulic)
The calcium oxide is then spent (slaked) mixing it with water to make
slaked lime (calcium hydroxide):

Once the excess water is completely evaporated (this process is technically
called setting), the carbonation starts:
1.3 Main Components in Concrete
(A) Cement (Non-hydraulic)
This reaction is slow, because the partial pressure of carbon dioxide in the
air is low ( ~ 0.4 millibar).
The carbonation reaction requires that the dry cement be exposed to air, so
the slaked lime is a non-hydraulic cement and cannot be used under water.
1.3 Main Components in Concrete
(A) Cement (Hydraulic)
The chemical reaction results in mineral hydrates
that are not very water-soluble and so are quite
durable in water and safe from chemical
attack.
This allows setting in wet conditions or under
water and further protects the hardened material
from chemical attack.
The chemical process for hydraulic cement was
found by ancient Romans who used volcanic ash
(pozzolana) with added lime (calcium oxide).
1.3 Main Components in Concrete
(A) Cement (Hydraulic)
By far the most common type of cement is
hydraulic cement, which hardens by
hydration of the clinker minerals when water
is added.
Hydraulic cements (such as Portland cement)
are made of a mixture of silicates and oxides.
1.3 Main Components in Concrete
(A) Cement (Hydraulic)
The four main minerals phases of the clinker, abbreviated in the cement
chemist notation, being:
1.3 Main Components in Concrete
(A) Cement (Hydraulic)
The tricalcium aluminate and
Tetra Calcium Alumino Ferrite
are essential for the formation of
the liquid phase during the
sintering (firing) process of
clinker at high temperature in the
kiln.
1.3 Main Components in Concrete
(A) Cement (Hydraulic)
First, the limestone (calcium carbonate) is burned to remove its carbon,
producing lime (calcium oxide) in what is known as a calcination reaction.
This single chemical reaction is a major emitter of global carbon dioxide
emissions.
1.3 Main Components in Concrete
(A) Cement (Hydraulic)
The lime reacts with silicon dioxide to produce dicalcium silicate and
tricalcium silicate.

The lime also reacts with aluminium oxide to form tricalcium aluminate.
1.3 Main Components in Concrete
(A) Cement (Hydraulic)
The lime also reacts together with aluminium oxide, and ferric oxide to
form cement.
1.3 Main Components in Concrete
(B) Fine Aggregate (Sand)
Definition: Small-size granular materials, typically sand or crushed stone,
used in concrete mixes. They help fill voids between larger aggregates,
improving the overall density of the concrete.
Size: Typically particles smaller than 4.75 mm.
Types:
(a) Natural sand: Obtained from riverbeds or seashores.
(b) Manufactured sand (M-sand): Crushed stone sand produced in a
quarry or crushing site.
1.3 Main Components in Concrete
(B) Fine Aggregate
Shape and texture:
(a) Round particles improve workability.
(b) Angular particles provide better bonding.
Fineness modulus: A measure of the particles size distribution. The
optimal range is 2.3 to 3.1 for concrete.
Considerations in selection:
(a) Must be clean and free from silt, clay and organic impurities, as these
can weaken the concrete.
1.3 Main Components in Concrete
(C) Coarse Aggregate (Gravel)
Definition: Larger pieces of crushed rock or gravel that are mixed with
cement and water to form concrete. They provide bulk, strength and
stability to the concrete structure.
Size: Particles larger than 4.75 mm. Common sizes used in concrete range
from 10 mm and 20 mm.
Types:
(a) Natural gravel: Rounded stone from riverbeds.
(b) Crushed stone: Sharp, angular stones produced from quarrying rocks.
1.3 Main Components in Concrete
(C) Coarse Aggregate
Shape and texture:
(a) Angular aggregates interlock better, providing stronger bonding.
(b) Rounded aggregates contribute to higher workability but may reduce
strength.
Surface texture: Rough textures provide better adhesion with cement paste.
Considerations in selection:
(a) Size should be chosen based on the type of structure (e.g., smaller
aggregates for smoother finishes or heavily reinforced sections).
1.3 Main Components in Concrete
(D) Water
Used for mixing concrete should be free from substances such as silt, soil,
organic acids and other organic materials such as salt and alkali.
Role in hydration process: Essential for the chemical reaction between
cement and water, known as hydration. This reaction forms calcium silicate
hydrate (C-S-H), which gives concrete its strength.
Role in workability: Water lubricates the mix, allowing it to be easily
shaped and moulded. Th right amount of water ensures that the concrete is
workable without being too fluid.
1.3 Main Components in Concrete
(D) Water
Types of Water Suitable for Concrete:
(a) Portable water: Fit for drinking is suitable for concrete.
(b) Water containing impurities such as salts, oils, acids, or organic
materials can weaken the concrete, causing long-term durability issues
(e.g., corrosion of reinforcements).
Considerations in water quality: Should be free from harmful chemicals
such as chloride or sulphates that can react with the cement and weaken the
concrete.
1.3 Main Components in Concrete
Take a break..
1.4 Types of Portland Cement
Ordinary
Portland
Cement
(OPC) Rapid-
High Strength
Hardening
Portland
Portland
Cement
Cement
(HSPC)
(RHPC)

Types of
Sulphate Portland White &
Resisting Cement Coloured
Portland
Portland
Cement
Cement
(SRPC)

Low Heat
Portland-
Portland
Blast Furnace
Cement
Cement
(LHPC)
1.4 Types of Portland Cement
(A) Ordinary Portland Cement (OPC)
Definition: OPC is the most common type of cement used in
general construction work. Made primarily from limestone
and clay, containing calcium silicate, alumina and iron oxide.
Application: Used in general construction where special
properties like rapid hardening or resistance to sulphate are
not required.
Advantages:
(a) Good strength development.
(b) Suitable for any general construction purposes.
1.4 Types of Portland Cement
(B) Rapid-Hardening Portland Cement (RHPC)
Composition: RHPC is a special type of cement that gains
strength faster than OPC. It contains higher amounts of
tri-calcium silicate (C3S) to enhance early strength.
Applications: Used in construction requiring fast-setting
cement, such as in pre-cast concrete, repairs and road
works.
Advantages:
(a) Attains high strength in early stages.
(b) Reduces project completion time.
1.4 Types of Portland Cement
(B) Rapid-Hardening Portland Cement (RHPC)
Advantages:
(a) Rapid hardening cement needs the shortest
time to set up and consolidate. It achieves
higher strength on lesser days.
(b) It can attain three (3) days strength in
equivalent to seven (7) days strength of
normal strength concrete.
1.4 Types of Portland Cement
(C) White & Coloured Portland Cement
White Portland Cement:
Composition: Low in iron and manganese,
which prevents coloration.
Made up: Using white clinker (containing little
or no iron) and white supplementary materials
such as high-purity metakaolin.
Applications: Used for aesthetic purposes in
architectural finishes like tiles, flooring and
decorative works.
1.4 Types of Portland Cement
(C) White & Coloured Portland Cement
Coloured Portland Cement:
Composition: Produced by adding pigments during
the manufacturing process.
Applications: Used for aesthetic purposes in projects
requiring specific colours for architectural appeal,
such as tiles or decorative facades. Other standards
(e.g., ASTM) do not allow pigments in Portland
cement and coloured cements are sold as blended
hydraulic cements.
1.4 Types of Portland Cement
(D) Low Heat Portland Cement (LHPC)
Definition: Specifically designed to produce less heat during
the hydration process, reducing the risk of cracking in large
structures.
Composition: Lower in tri-calcium silicate (C3S) and higher
in di-calcium silicate (C2S), which produces less heat.
Applications: Used in mass concrete structures such as dams,
bridges and large foundations.
Advantages: Minimizes thermal cracking in large structures
due to lower heat generation.
1.4 Types of Portland Cement
(D) Low Heat Portland Cement (LHPC)
1.4 Types of Portland Cement
(E) Portland-Blast Furnace Cement
Definition: A blend of Portland cement
and granulated blast furnace slag.
Composition: Contains 25-70% blast
furnace slag, which improves
durability.
Applications: Used in marine
structures, concrete exposed to
sulphates and general construction
where enhanced durability is required.
1.4 Types of Portland Cement
(F) Sulphate Resisting Portland Cement (SRPC)
Definition: Designed to resist sulphate attacks, which
can cause expansion and cracking in concrete.
Composition: Lower in tri-calcium aluminate (𝑪𝟑 𝑨),
the compound that reacts with sulphates.
Applications: Ideal for foundations, sewerage
treatment plants and structure exposed to soils or water
high in sulphates.
Advantages: Prevents deterioration in sulphate-rich
environments, ensuring structural durability.
1.4 Types of Portland Cement
(G) High Strength Portland Cement (HSPC)
Definition: A type of Portland cement with
higher compressive strength than OPC.
Composition: Similar to OPC but has a
lower water-cement ratio and finer
particles.
Applications: Used in high-performance
structures, such as high-rise buildings,
bridges and tunnels where higher strength is
required.
1.4 Types of Portland Cement
(H) Masonry Cement
Definition: A special type of cement used in the
construction of masonry structures such as
brickwork, plaster and block laying.
Composition: Blended with lime or other fine
materials to improve workability and cohesion.
Applications: Used for plastering, brick/block
laying and other non-load-bearing masonry
applications.
1.4 Types of Portland Cement
(I) Air Entraining Cement
Composition: A special cement which has air
bubbles introduced in the cement or concrete that
provides the space for expansion of minute
droplets of waters in the concrete due to freezing
and thawing and protects from cracks and
damage of concrete.
Advantageous:
(a) Bleeding, segregation and laitance in
concrete reduces.
(b) Entraining air improves the sulphate resisting
capacity of concrete.
1.5 Main Properties of Portland Cement
(A) Portland Cement Composition – Chemical Properties

Oxide Content (%)
Lime (𝐶𝑎𝑂) 60 – 67
Silica (𝑆𝑖𝑂2 ) 17 – 25
Alumina (𝐴𝑙2 𝑂3 ) 3–8
Iron Oxide (𝐹𝑒2 𝑂3 ) 0.5 – 6.0
Magnesia (𝑀𝑔𝑂) 0.1 – 4.0
Sulphur Trioxide (𝑆𝑂3 ) 1–3
Soda and/or Potash (𝑁𝑎2 𝑂 + 𝐾2 𝑂) 0.5 – 1.3
1.5 Main Properties of Portland Cement
(B) Typical Oxide Composition – Chemical Properties

Oxide Content (%)
Lime (𝐶𝑎𝑂) 63
Silica (𝑆𝑖𝑂2 ) 20 𝐶2 𝑆 = 17%
Alumina (𝐴𝑙2 𝑂3 ) 6 𝐶3 𝑆 = 54%
Iron Oxide (𝐹𝑒2 𝑂3 ) 3 𝐶3 𝐴 = 11%
Magnesia (𝑀𝑔𝑂) 1.5 𝐶4 𝐴𝐹 = 9%
Sulphur Trioxide (𝑆𝑂3 ) 2
Soda and/or Potash (𝑁𝑎2 𝑂 + 𝐾2 𝑂) 1
1.5 Main Properties of Portland Cement
(C) Hydration Characteristics
Compounds Reaction Rate Strength Heat Liberation
𝐶3 𝑆 Moderate High High
𝐶2 𝑆 Slow Low initially; High Later Low
𝐶3 𝐴 + 𝐶2 𝐻2 Fast Low Very high
𝐶4 𝐴𝐹 + 𝐶𝑆𝐻2 Moderate Low Moderate
1.5 Main Properties of Portland Cement
(C) Hydration Characteristics (Rate of Hydration)
1.5 Main Properties of Portland Cement
(C) Hydration Characteristics (Rate of Hydration)
1.5 Main Properties of Portland Cement
(C) Hydration Characteristics
Hydration of cement is the key to
concrete’s performance in terms of
durability and strength.
Definition: Heat generated when cement
and water react. The amount of heat
generated is dependent upon the
chemical composition of the cement,
with 𝑪𝟑 𝑨 and 𝑪𝟑 𝑺 being the compounds
primarily responsible for high heat
evolution.
1.5 Main Properties of Portland Cement
(C) Hydration Characteristics (Hydration Phases)

Cement particles reacts with water (𝐻2 𝑂).

𝐶3 𝐴 reacts quickly with water to form ettringite crystals.

Later, slower growing calcium silicate hydrate (C-S-H) crystals also form.
Generally, the slower the crystal growth, the greater the eventual strength.
Hydration products are gel plus 𝑪𝒂(𝑶𝑯)𝟐
1.5 Main Properties of Portland Cement
(C) Hydration Characteristics (Hydration Phases)

Initial crystal growth causes only a slight stiffening
of the paste, as the cement particles are far enough
not to interact.
But as the crystals grow and intersect, setting
(stiffening of the paste) and eventually hardening
(strength increase occurs).
The closer the particles, i.e. the lower the water-to-
cement ratio, the higher the eventual strength, density
and durability.
1.5 Main Properties of Portland Cement
(D) Physical Properties

Properties Values
Specific Gravity 3.16
Normal Consistency 29%
Initial Setting Time 65 mins
Final Setting Time 275 mins
2
Fineness 330 𝑘𝑔Τ𝑚
Soundness 2.5 mm
3
Bulk Density 830 – 1650 𝑘𝑔Τ𝑚
1.5 Main Properties of Portland Cement
(E) Strength Development
 THANK YOU…

Prepared by:
Dr. Faisal Amsyar
[email protected]
0138370829