Cement Materials PDF

Summary

This document provides a lecture on engineering materials, specifically focusing on cement. It covers various aspects such as its composition, types (natural and artificial), manufacturing processes, and properties.

Full Transcript

CE 201
Engineering Materials

Construction Material : CEMENT
 INTRODUCTION TO CIVIL ENGINEERING MATERIALS
Civil Engineering encompasses the

❑ conception, design, construction, and management of residential and
commercial buildings and structures,
❑ water supply facilities, and transportation systems
❑ control of the environment

for the maintenance and improvement of the quality of life.
Various types of materials are used for construction of
buildings, highways, bridges, etc.

Natural materials:
→Unprocessed, raw, minimally processed
(Stone, rock, sand, wood etc.)

Synthetic materials
→Industrial processing
→Artificially composed
(Cement, tiles, concrete, steel etc.)
Material Selection
Wood
Lumber, Plywood, Composites

Steel
Shapes, Rebar, Pipes,
Cold-Formed, Cable
Material Selection

Concrete
Cast, Precast, Grout, Mortar

Stone and Masonry
Brick, Concrete Block, Cut-Stone
Material Selection
Asphalt
Hot-mixed, Cold-mixed, Emulsions

Aluminum
Shapes, Pipe, Cold-Formed
Material Selection
Architectural Materials
Tile, Glass, Acoustic Tile

Soil
Foundations, Fill, Embankment, Liner
▪ Selection of construction materials involves a wide spectrum of choices.

▪ The selection is often based on economic, environmental, availability, or
technical considerations.

▪ Geography often determines the economic and availability
considerations and engineering principals typically control the technical
and environmental considerations.
Civil Engineering design is based on relationships between-
Stress vs. Strength
Strain vs. Deflection
Exposure vs. Durability
Risk vs. Consequence
Cost vs. Aesthetics & Life Cycle
 CONSTRUCTION MATERIAL : CEMENT

Cement is finely ground (powdered), inorganic & hydraulic material
Cement is the active ingredient in concrete.

→
▪ Cement acts as the binder material in construction works
▪ When mixed with water, forms a paste which sets and hardens by means of
hydration reactions

▪ After hardening, retains specified strength levels and also long-term volume
stability even under water
History of Cement

Cyclopean masonry of Greece
- no cementing material
Ancient Egyptian buildings
- Stone & unbaked brick
- covered with Nile mud
Mesopotamians used bitumen as an adhesive in building structure
▪ First cements produced by early Greeks and Romans from volcanic ash
mixed with slaked lime.
▪ This art was lost during the Middle Ages
▪ Portland cement – the modern artificial form of cement was developed in
England by bricklayer Joseph Aspdin in 1824.

▪ Aspdin found that by heating clay and limestone at a very high
temperature, then cooling, grinding and mixing it with water he had created
particularly strong cement.

▪ This cement is named called “Portland” because concrete made with it
resembled natural stone from the Isle of Portland.

▪ Today, portland cement is the most widely used building material in the
world with about 3 billion tons produced each year.
Classification of Cement
▪ Cement is the mixture of calcareous (calcite/ CaCO3), siliceous (consisting
silica) , argillaceous (clay) and other substances

▪ According to source of raw material used cement can be classified as-:
- Natural cements
- Artificial cements
 Natural cement
▪ Manufactured from natural stones by burning and then crushing to
powder
▪ These stones contain 20~40% of argillaceous matter and the rest as
calcareous matter
▪ As the chemical composition of natural cement stones varies
considerably - the properties of natural cement also keep on varying.

CE 201: Lecture on Cement by Snigdha Afsana, Asst Professor, Dept. of CE, BUET
Artificial cement
▪ manufactured by burning at high temperature an intimate mixture of
argillaceous and calcareous substances and lastly crushing the resulting
clinkers to a fine powder after adding a little gypsum to it.
▪ Gypsum is added to delay the setting action of the cement
Artificial cement is popular because of the following reasons:
▪ Can be manufactured in any desired color.
▪ Initial setting time can be easily regulated.
▪ Rate of hardening and heat evolution can be regulated.
▪ Quality cement can be easily controlled maintaining the same
composition of raw materials.
▪ Can be manufactured in very large quantity.
Composition of Portland Cement
The chief chemical components of portland cement are- calcium, silica,
alumina and iron.
Calcium is derived from limestone, marble or chalk,
Silica, alumina and iron come from the sands, clays and iron ore
respectively
Other raw materials may include shale, shells and industrial byproducts
such as mill scale etc.
CE 201: Lecture on Cement by Snigdha Afsana, Asst Professor, Dept. of CE, BUET
a) Limestone (CaCO3) is mainly providing calcium in the form of calcium
oxide (CaO)
CaCO3 (1000 0C) → CaO + CO2

b) Clay is mainly providing silicates (SiO2) together with small amounts of
Al2O3 + Fe2O3
Clay (1450oC) → SiO2 + Al2O3 + Fe2O3 + H2O
c) Iron ore and Bauxite are providing additional aluminum and iron oxide
(Fe2O3) which help the formation of calcium silicates at low temperature. They
are incorporated into the raw mix.

Then Ordinary Portland Cement (OPC) produced by heating limestone and
clay minerals in a kiln to about 1400 to 1600°C - the temperature range in
which the two materials interact chemically to form calcium silicates
Hydration of Cement (Cement Reaction with Water)
❑ When Portland cement is mixed with water its chemical constituents
undergoes a series of chemical reactions that cause Setting &
Hardening of cement.

❑ In short,
- Setting is the process of retaining the shape
- Hardening is the process of gaining strength
❑ The phase compositions in portland cement are denoted by ASTM as
i. tricalcium silicate (C3S)- [3CaO.SiO2 ]

ii. dicalcium silicate (C2S) -[2CaO.SiO2 ]

iii. tricalcium aluminate (C3A)- [3CaO. Al2O3 ] and

iv. tetracalcium aluminoferrite (C4AF) [4CaO.Al2O3.Fe2O]

❑ The behavior of each type of cement depends on the content of these
components.
i. Tricalcium silicate (C3S):

Also known as “alite”.
Hydrates and hardens rapidly.
Largely responsible for initial set and early strength.
Portland cements with higher percentages of C3S will exhibit higher
early strength.

C3S + 3H --> C-S-H + 2C-H
(rigid gel)
ii. Dicalcium silicate (C2S):

Also known as “belite”.
Hydrates and hardens slowly continues for several weeks.
Largely responsible for strength increases beyond one week.

C2S + 2H --> C-S-H + C-H
(rigid gel)
iii. Tricalcium aluminate (C3A):

▪ Hydrates and hardens the quickest.
▪ Liberates a large amount of heat almost immediately and contributes
very little to early strength.
▪ Gypsum is added to portland cement to retard C3A hydration. Without
gypsum, C3A hydration would cause portland cement to set almost
immediately after adding water.
iv. Tetracalcium aluminoferrite (C4AF):

▪ Hydrates rapidly but contributes very little to strength.
▪ Its use allows lower kiln temperatures in portland cement
manufacturing.
▪ Most portland cement color effects are due to C4AF.
Strength development rate of major constituents of cement

Setting
Vs
Hardening??
 Heat of Hydration
▪ The Hydration of cement with water is exothermic (a chemical reaction
that releases light or heat)
▪ The liberation of heat is called heat of heat of hydration.
▪ This process of hydration of cement results to the formation of minute
crystals of calcium and gels from the solution of cement and water and it
continues for a long time.
▪ As considerable amount of heat is evolved during hydration of cement,
study and control of hydration becomes important in mass
construction(e.g., piers, dams etc.)
 As the crystals adhere to one another and to the surface of sand or inert
particles of aggregate (with which cement is mixed), the entire mixture
gets set and hardened resulting in gaining strength.
The strength developed depends on the amount of gel formed, and the
degree of crystallization.
▪ The hydration rate of cement constituents is highly variable.
▪ The rate of hydration during the first few days -

C3A >C3S > C4AF >C2S
▪ Usually, the greatest rate of heat liberation occurs within the first 24 hours
and a large amount of heat evolves within the first 3 days.
▪ However Portland cement evolves heat for a long time

▪ One gram of OPC Type-I gives out about 120 calories on setting over 13
years, out of which 80 calories are given out in the first 7 days.
Calorimetric curve of Portland Cement Hydration Process
Ettringite (C6AS3H2) Hydrous calcium aluminium sulfate mineral
Ca6Al2(SO4)3(OH)12·26H2O

Ettringite is formed in hydrated Portland cement system as a result of the
reaction of calcium aluminate (C3A) with gypsum,

C3A + 3 CaSO4 → ettringite
 12-36 hrs

10-15 mins IST FST
 The first heat peak is completed in 10 to 15 min and then the rate of heat evolution has been
reduced to a very lower value due to the formation of the ettringite barrier. The heat of hydration
remains at low value till the ettringite barrier is broken by transformation of ettringite to mono-
sulfoaluminate after all the gypsum has been used to form the ettringite.
The more gypsum there is in cement, the longer the ettringite will remain stable. In most cements
ettringite remains in stable condition for a period of 12 to 36 hours. This is the reason why the
concrete remains in plastic state for several hours.
The rate of heat evolution starts increasing with start of ettringite conversion to monosulfo- aluminate
and reaches to the second heat peak. By this time (4 to 8 h) final set has been passed and early
hardening has begun and then again starts decreasing approaching to a steady-state condition.
 Types of Portland cements
▪ Different types of portland cement are manufactured to meet different physical and
chemical requirements for specific purposes, such as durability and high-early
strength.
▪ Classification as per AASHTO M 85 and ASTM C 150,
1. Type I - Ordinary Portland cement
2. Type IA - Normal-Air Entraining
3. Type II - Moderate Sulfate Resistance
4. Type IIA - Moderate Sulfate Resistance Air Entraining
5. Type III - High Early Strength
6. Type IIIA – Air Entraining Early Strength
7. Type IV - Low Heat of Hydration
8. Type V - High Sulfate Resistance
1. Type I - Ordinary Portland cement
▪ Known as common or general purpose cement.
▪ Commonly used for constructions especially those concrete constructions
not to be in contact with soil or ground water
▪ Fairly high C3S content causes good early strength development
Table: Main Constituents in a Typical Portland Cement (Type-1)

Chemical Name Shorthand
% by Weight
Notation

Tricalcium Silicate (Alite) C3S 50

Dicalcium Silicate (Belite) C2S 25

Tricalcium Aluminate C3A 12

Tetracalcium C4AF 8
Aluminoferrite (Ferrite)

Gypsum CSH2 3.5
2. Type IA - Normal-Air Entraining OPC
▪ An air-entraining modification of Type I.
▪ Use 0.001 to 0.1% by weight air entraining or foaming agents
(e.g., vinsol, resin, darex etc) are added during grinding of clinkers.
▪ When water is added this air entraining agents create tiny air bubbles in
the cement mix and prevent contact of cement particles with each other
and thus delay setting.
3. Type II - Moderate Sulfate Resistance Cement
▪ Also known as expanding Portland cement
▪ Used as a precaution against moderate sulfate attack.
▪ Used for structures exposed to soil or water containing sulfate ions
▪ It will usually generate less heat at a slower rate than Type I cement.
▪ Low C3A content

C 3S C2S C 3A C4AF
45 30 7 12
4. Type II - Moderate Sulfate Resistance Cement
Sulfate attack is an important phenomenon that can cause severe damage to
concrete structures. It is a chemical reaction between the hydration products
of C3A and sulfate ions that enter the concrete from the outside environment.
The products generated by this reaction have a larger volume than the
reactants, and this creates stresses which force the concrete to expand and
crack.
4. Type IIA - Moderate Sulfate Resistance Air Entraining

- An air-entraining modification of Type II.
5.Type III - High Early Strength Cement
▪ A rapid hardening cement, is used when high early strength is needed
(e.g., highway slab, pre-cast concrete, cold weather concreting).
▪ It has more C3S than Type-I cement and has been ground finer to provide
a higher surface-to-volume ratio, both of which speed the rate of
hydration.
▪ Strength gain is double that of Type I cement in the first 24 hours.

C 3S C 2S C 3A C4AF
60 15 10 8
7. Type IV - Low Heat of Hydration Cement
▪ Used when hydration heat must be minimized in mass concrete structures
such as bridge, abutment, dams, raft, retaining walls etc.
▪ Such structures have low surface to volume ratio therefore heat
dissipation rate is much lower than that generated.
▪ Contains about half the C3S and C3A and double the C2S of Type I
cement.

C3S C2S C3A C4AF
25 50 5 12
8. Type V - High Sulfate Resistance Cement
▪ Used as a precaution against severe sulfate action - principally where the
concrete is in contact to soils or groundwater having high sulfate content.
▪ High sulfate resistance is attributable to low C3A (