The basic
components of cement mortar are cement, water and aggregates. But, other
substances are added to these three in preparing the cement mortar. The purpose
of these admixture is to improve the quality of the mortar.
there are
2 type of admixture
chemical
admixtures and mineral admixtures.
Mineral
admixtures are basically derived from other substances and not chemically
manufactured. Fly ash, blast furnace slag, silica fume are popular examples of
mineral admixtures.
Important Mineral Admixtures And Their Effect On
Concrete
Fly ash,
ground
granulated blast furnace slag
silica
fume
most
commonly used mineral admixtures. They have different roles to play in the
concrete mix and enhance various properties of the concrete.
Admixture-1: Fly Ash
Pulverized
coal is combusted in thermal power plants for electricity generation. A
by-product of this combustion reaction is fly ash. The electrostatic
precipitators (ESPs) used inside chimneys of the power plants remove fly ash
before ejecting out the combustion gases into the atmosphere. Fly ash is a very
fine particle like residue, which has pozzolanic properties. Hence it is often
blended with cement.
Fly ash
consists of silica (SiO2), alumina (Al2O3) and
calcium oxide (CaO) as its major components. Fly ash can be of two types – C
type and F type. C type fly ash is rich in calcium and possesses both
cementitious and pozzolanic properties whereas F type fly ash is low in calcium
content and possesses only pozzolanic properties.
- Fly ash particles are mostly
spherical and increase the workability of concrete.
- The setting time of concrete
is also increased by adding fly ash to it. Increased setting time allows
better hardening of concrete and finally a better strength is obtained.
- Fly ash added to concrete
mix reduces the segregation and bleeding of concrete. Segregation of
concrete is a case in which particles of different size tend to segregate
out. Whereas bleeding of concrete is a situation in which water comes out
to the surface of the concrete. Both segregation and bleeding are
unwanted.
- The temperature of fresh
concrete rises above normal and when it cools down, cracks may develop.
Replacing a certain quantity of cement by fly ash helps to reduce this
temperature rise, hence avoiding chances of cracking of fresh concrete.
- Creep and shrinkage are
usually higher in fly ash added concrete because of the increased amount
of paste in the concrete (formed due to mass replacement of cement).
- Sulphate resistance is
enhanced.
- Alkali aggregate reaction is
inhibited.
Fly ash
Admixture-2: Ground Granulated Blast Furnace Slag
(GGBFS)
Blast
furnace slag is a by-product of iron extraction process from iron ore. Amongst
all mineral admixtures, blast furnace slag has the highest specific gravity
(2.8 to 3.0). Typically, the slag fineness is slightly more than that of the
cement.
There are
various types of slag possible like air cooled slag, expanded or foamed slag,
granulated slag and pelletized slag. Among these only the granulated slag is
commonly used as a mineral admixture. It is a highly reactive form of slag and
is usually quenched to form a hardened matter which is then ground into
particles of fineness almost same as that of cement. Hence the name, ground
granulated blast furnace slag.
GGBFS
possesses both cementitious and pozzolanic properties. An activator is needed
to hydrate the slag.
- GGBFS increases the initial
setting time of the concrete. But, it does not alter the workability of
the concrete much because its fineness is almost same as that of the
cement.
- The rate of strength gain of
concrete is diminished by replacement of cement in the concrete with
GGBFS.
- The ultimate strength gain
is improved by slag replacement and also the durability of the concrete is
increased.
- Concrete uses in marine
purposes is highly prone to chemical attack and corrosion. GGBFS is a very
good admixture in this regard, because it increases resistance to these
attacks.
- However, concrete with GGBFS
is reported to have higher carbonation rates than normal Portland cement
concrete.
Ground
Granulated Blast Furnace Slag (GGBFS)
Admixture-3: Silica Fume
Silica
fume is basically very fine particles of amorphous silica. It is produced as a
by-product in electric arc furnaces in the production of elemental silica or
other silicon based compounds.
Silica
fume is highly pozzolanic in nature.
- Being of very fine nature,
silica fume increases the water demand of concrete and hence a
superplasticizer is almost always used with it.
- Silica fume makes the
concrete mix stickier and more cohesive. Usually slump loss problems arise
due to addition of silica fume to the concrete.
- There is a drastic reduction
in the bleeding of concrete.
- Plastic shrinkage may occur
in dry regions where evaporation rate exceeds the rate at which concrete
sets.
- The permeability of concrete
is reduced. Silica fume acts both as a pozzolan and a filler and due to consequent
reactions the transition zone between the aggregates and cement paste is
strengthened. Chloride permeability is reduced significantly.
- Compressive and flexural
strength of concrete is enhanced. The elastic modulus of concrete is also
increased by about 15 % compared to normal Portland cement concrete.
Increased elastic modulus implies that the stiffness of the concrete is
increased.
- Creep and shrinkage are also
increased at higher replacement levels of 10 – 15 %. However, the
resistance to creep and shrinkage deformation is also increased because of
the increase in stiffness.
- Silica fume concrete mostly
shows good resistance to chemical attacks due to the reduced permeability
(exceptions of ammonium sulphate and magnesium sulphate are there).
- Silica fume concrete is
ideal for industrial flooring because it provides excellent resistance to
abrasion and erosion.
- Fire resistance of silica
fume concrete is not impressive. It does not allow the entrapped water to
vaporise out because of its low permeability. Hence, due to high pressures
developing inside, the concrete tends to crack.
- Carbonation depth is usually
lowered.
Silica
Fumes
Admixture-4: Rice Husk Ash
During
milling of the paddy coming from fields, a lot of rice husk is produced. This
rice husk is mostly used as a fuel. Rice husk ash is produced by burning the
rice husk. It is about a quarter of the mass of the husk. The rice husk ash is
a big threat to the environment where it is dumped.
Rice husk
ash can be produced by field burning (open) – produces poor quality ash, bed
furnace burning (fluidized) and industrial furnace.
Rice husk
ash contains a high amount of silica.
- Rice husk ash provides strength
to the concrete.
- It also reduces permeability
because it is much smaller in size compared to cement particles.
- It reduces the heat of
hydration of concrete.
- Rice husk ash also improves
the concrete’s resistance to chloride and sulphate attacks.
Rice Husk
Ash
Admixture-5: Metakaolin
Ordinary
clay and kaolin clay when thermally activated, is called metakaolin, in the
non-purified form. The particle size of metakaolin is smaller than cement
particles. Metakaolin is not an industrial by-product like the other
admixtures.
- Metakaolin provides strength
to the concrete.
- It reduces permeability of
the concrete.
- It helps the concrete resist
chemical attacks.
- It makes the concrete more
durable.
- It helps in early strength
development in concrete.
- Bleeding of concrete is
considerably reduced upon metakaolin addition.
Metakaolin
is also used in fibre-cement and ferro-cement products. It is also used in art
sculptures.
Metakolin
Comparison Of Various Mineral Admixtures Based On
Various Properties
|
|
Fly ash |
GGBFS |
Silica
fume |
Rice
husk ash |
Metakaolin |
|
Physical
characteristics |
Greyish,
lightweight & fine particles |
Off
white powdery substance heavier than fly ash |
Amorphous,
very fine particles, heavier than fly ash |
Amorphous,
very lightweight, fine particles. (Threat to environment.) |
Whitish
in colour & fine particles. |
|
Chemical
composition |
20 – 60
% silica 5 – 35
% Al2O3 1 – 12
% CaO Traces
of MgO |
28 – 38
% silica 8 – 24
% Al2O3 30 – 50
% CaO 1 – 18
% MgO |
85 %
silica 1 % Al2O3 6 % Fe2O3 12 %
carbon |
90 %
silica 5 %
carbon 3 % K2O |
Dehydroxilated
form of kaolinite clay |
|
Source |
By-product
in thermal power plants |
By-product
in iron producing blast furnaces |
By-product
in silicon producing electric arc furnaces |
From
rice husk |
From
kaolinite clay |
|
%
addition in concrete |
Upto 30
% cement replacement |
25 – 70
% cement replacement |
3 – 4
parts of cement replacement per 1 part of silica fume |
Around
20 % cement replacement |
8 – 10
% cement replacement |
|
Advantages
of addition |
Improves
strength and durability of concrete Increased
resistance towards chemical attacks Better
workability |
Improved
durability Increased
setting time Strength
gain continues for a long period of time Reduced
risk of damages by alkali – silica reaction Resistant
to chloride and sulphate attacks |
Better
compressive strength and resistance to abrasion Reduced
permeability of chloride ions Improved
workability Reduces
bleeding |
Heat of
hydration of concrete is reduced Permeability
of concrete is reduced Improved
resistance to chloride and sulphate attacks |
Increased
compressive & flexural strengths Reduced
permeability More
resistant to chemical attacks Durability
is increased |
|
Availability |
Produced
in abundance but availability is poor |
Sufficient
amount of GGBFS is available |
Sufficient
quantity of silica fume is available |
Abundant |
Abundant |
In
general, all mineral admixtures reduce bleeding of concrete. Admixtures with
finer particle size and higher specific surface area are suitable for preparing
high density and low permeability concrete.
Increase
in water demand due to addition of admixtures may be handled by the use of an
effective superplasticizer. All these factors contribute significantly to
the rise in use of mineral admixtures. If used properly these can immensely
increase the desirable properties of the concrete. Otherwise there is no repair
for the poor quality of concrete mix ingredients.
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