Geo Polymer Concrete
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Transcript of Geo Polymer Concrete
GEO POLYMER CONCRETE(CONCRETE WITHOUT CEMENT OR LITTLE CEMENT)
INDEX
• Introduction• Constituents of geo polymers• Manufacturing process• Economic benifits and Hurdles• Conclusion• References
INTRODUCTION
1.1 General:
The basic and most important constructional material for infrastructural development is
ordinary portland cement-OPC. Ordinary portland cement(OPC) is conventionally used as the
Primary binder to produce concrete. The environmental issues associated with the OPC are
Well known. The amount of the carbon dioxide released during the manufacture of OPC due to
The calcination of the limestone and combustion of fossil fuel is in the order of one ton for every
Ton of OPC produced. In addition, the extent of energy required to produce OPC is only next
To steel and aluminium .
India is third largest cement producing country in the world, next only to china and japan
Despite OPC being highly valuable and wonderful building material, it suffers from variety of
Maladies. The maladies include depletion of natural resources like lime stone in production
Of OPC, large amounts of energy consumption in manufacture results in global warming and
Climate change, cause panic in the whole world, spiraling cost of OPC in developing countries
Like India . research has been in progress all over the world accruing several benefits replacement
Of OPC with CCMS(Complimentary Cementing materials) like Rice husk ash, silica fume , flyash
And others has negated the ill effects of OPC to a large extent. Further the availability of fly ash
Worldwide creates opportunity to utilize this by-products of burning coal, as a substitute for OPC
To manufacture concrete.
CONT-
when used as a partial replacement of OPC , in the presence of water and in ambient
Temperature , fly ash reacts with the calcium hydroxide during the hydration process of OPC to
Form the calcium silicate hydrate (C-S-H) gel. The development and application of high volume
Fly ash concrete, which enabled the replacement of OPC up to 60% by mass is a significant
Development.
In 1978, Davidovits proposed that binders could be prepared by a polymeric reaction
Of alkaline liquids with the silicon and the aluminium in sources materials of geological origin or
By-products materials such as fly ash and these binders are known as geo-polymers . The main
Binders produced is a C-S-H gel, as the result of the hydration process.
1.2 Low-calcium Fly-Ash based Geo-ploymer Concrete:
Reacting alumino silicate minerals with highly alkaline solution forms geo-
polymers. concrete manufactured with such geo-polymers is known as GEOPOLYMER
CONCRETE. The alumino silicate minerals to be used are class-F fly ash and alkaline
Solutions to be used are sodium hydroxide solution, sodium silicate solution. In this
Work, low-calcium fly ash-based geo-ploymer is used as the binder, instead ofPortland
Or other hydraulic paste, to produce concrete. The fly ash based geo-polymer paste
Binds the loose coarse aggregates, fine aggregates and other un-reacted materials
Together to form the geo-polymer concrete, with or without the presence of admixtures.
The manufacture of geo-polymer concrete is carried out using the usual concrete
Technology methods.
As in the case of OPC concrete, the aggregate occupy about 75-80% by
Mass, in geo-polymer concrete. The silicon and the aluminium is the low-calcium fly-
ash react with an alkaline liquid that is a combination of sodium silicate and sodium-
hydroxide solution to form the geo-polymer paste that binds the aggregates and other
un-reacted materials.
1.3Fly ash:
According to the American Concrete Institute(ACI) Committee 116R, fly is defined as
‘the finely divided residue that results from the combustion of ground or powdered coal and that
Is transported by flue gasses from the combusyion zone to the particle removal system’. Fly ash
Is removed from the combustion gases by the dust collection system, either mechanically or by
Using electrostatic precipitators, before they are discharged to the atmosphere. Fly ash paticles
Are typically spherical, finer than portland cement and lime, rangling in diameter from less than
1µm to more than 150µm.
The types and relative amounts of incombustible matter in the coal determine the chemical
Composition of fly ash. The chemical composition is mainly composed of the oxides of
silicon(SiO2), Aluminium (Al2O3), iron(Fe2O3), and calcium(CaO), whereas magnesium.
potassium, sodium, titanium, and sulphur are also present in a lesser amount.
1.4 Geo-polymers:
Davidovits proposed that an alkaline liquid could be used to react with the silicon(si) and
the aluminium (al) in a source material of geological origin or in byproduct materials such as fly
ash and rice husk ash to produce binders. Because the chemical reaction that takes place in this
case is a polymerization process. Geo-Polymers are members of the family of inorganic polymers.
The chemical composition of the geo-polymer material is similar to natural zeolitic materials, but
The microstructure is amorphous instead of crystalline. The polymerization process invoves a sub-
Stantially fast chemical reaction under alkaline condition on si-al minerals, that results in a three
Dimensional polymeric chain and ring structure consisting of si-o-al-o bonds, as follows.
Mn[-(SiO2)z-AlO2]n.wH2O
Where: M=the alkaline element or cation such as potassium, sodium or calcium;
the symbol – indicates the presence of a bond, n is the degree of polycondensation
or polymerization;
z is 1,2,3, or higher, up to 32.
CONSTITUENTS OF GEOPOLYMERS
2.1Source materials:
Any material that contains mostly silicon(si) and Aluminium (al) in amorphous form is a possible
source material for the manufacture of geo-polymer. Metakaolin or calcined kaolin, low-calcium
ASTM class F fly ash, natural Al-Si minerals, combination of calculated mineral and non-calcined
Materials , combination of fly ash and metakaolin, and combination of granulated blast furnace
Slag and metakaolin can be taken as source materials.
low-calcium(ASTM class F) fly ash is preferred as a source material than highcalcium(ASTM
class F) fly ah. The presence of calcium in high amount may interfere with the polymerisation
process and alter the microstructure. Fly ash is considered to be advantageous due to its high
Reactivity that comes from its finer particle size than slag. Moreover, lowcalcium fly ash is more
Desirable than slag for geo-polymer feedstock material.
2.2Alkaline liquids :
The most common alkaline liquid used in geo-polymerisation is combination of sodium hydroxide
(NaOH) or potassium hydroxide(KOH) and sodium silicate or potassium silicate.
The type of alkaline liquid plays an important role in the polymerization process. Reactions
Occur at a high rate when the alkaline liquid contains soluble silicates, either sodium or potassium
Silicate, compared to the use of the only alkaline hydroxides. That the addition of sodium silicate
Solution to the sodium hydroxide solution as the alkaline liquid enhanced the reaction between the
source material and the solution. Among the geo-polymerisation of sixteen natural Al-Si minerals,
NaOH solution causes a higher extent of dissolution of minerals than the KOH solution.
MANUFACTURING PROCESS
3.1 Material Preparation:
Aggregates used in the manufacture the fly ash-based geo-polymer concrete were in asaturated-surface-dry (SSD) condition. The aggregate selection and proportion were in accordance with the current practice used in making OPC concrete. The alkaline liquid consisted of a combination of sodium silicate solution and sodium hydroxide solution. The sodium silicate solution was purchased from a local supplier. The sodium hydroxide solution was prepared by dissolving the solids, purchased from a local supplier in flakes or pellets form, in water. Both the solutions were premixed the day before use. The alka-line liquid was mixed with the super plasticiser, if any, and the extra-added water, if any, to prepare the liquid component of the geo-polymer concrete mixture.
3.2 Mixing, Placing, and Compaction:
The liquid component of the mixture was then added to the solids particles, and mixingcontinued for The aggregate and the fly ash were mixed dry in a pan mixer for about three minutes another four minutes in most cases. The fresh fly ash-based geo-polymer concrete could be handled up to at least two hours without any sign of setting and degradation in compressive strength. The fresh geo-polymer concrete could be placed, compacted, and finished in moulds in that time. In all these operations, the equipment and the facilities currently used for OPC concrete were used. For cylinder specimens of 100x200 mm, the mixture was cast in three layers. Eachlayerreceived 60 manual strokes, and vibrated for 10 seconds on a vibrating table. Insome cases, the common internal needle vibrator was also utilised to successfully compact the fly ash- based geo-polymer concrete.
PAN MIXER
DRY MATERILAS
ADDITION OF LIQUID COMPONENT
FRESH GEOPOLYMER CONCRETE READY FOR PLACING
COMPACTION INTO MOULDS
3.3 Curing:
After casting, the test specimens were covered by a vacuum bagging film. Curing at
an elevated temperature was achieved either in the dry curing environment in an
oven, or in the steam curing chamber, for a specified period of time. After curing, the
concrete specimens were allowed to cool down in the moulds. After releasing from
the moulds, the test specimens were left to air dry in ambient conditions in the
laboratory until the day of testing.
WRAPPING OF CONCRETE SPECIMENS BEFORE CURING
SPECIMEN IN STEAM CURING CHAMBER
Economic benefits:
Low-calcium fly ash-based geo-polymer concrete offers several economic benefits over
Portland cement concrete.
The cost of one ton of fly ash is only a small fraction, if not free in some parts of the world,
of the cost of one ton of Portland cement. In Australia, based on the current bulk cost of sodium
silicate solution and sodium hydroxide solids, we have estimated that the cost of chemicals nee-
ded to react one ton of fly ash is approximately AU $50. This is significantly smaller than the
current price of Portland cement. Therefore, low-calcium fly ash-based geo-polymer concrete is
cheaper than Portland cement concrete.
In addition, we have learnt that the appropriate usage of one ton of fly ash earns one carbon-
credit that currently has a redemption value of about 20 Euros. Based on the data given in this
Report, one ton low-calcium fly ash can be utilised to manufacture approximately 2.5 cubic
metres of good quality fly ash-based geo-polymer concrete, and hence earn monetary benefits
through carbon-credit trade.
Furthermore, the very little drying shrinkage, the low creep, the excellent resistance to sulfate
attack, and the good acid resistance offered by the low-calcium fly ash-based geopolymer
concrete provides additional economic benefits when used in infrastructure applications.
Hurdles for geo-polymer concrete:
• Different source materials
• Industry regulations
• Contaminants
• Properties of soluble silicate
• New material
CONCLUSION
• The reduce of CO2 emissions of geo-polymer concrete makes them a good alternative to
Ordinary portland cement.
• Produces a substance that is comparable to or better than traditional cements with respect
To most properties.
• Geo-polymer concrete has excellent properties with in both acid and salt environments.
• Low-calcium fly ash based geo-polymer concrete has excellent compressive strength and is
Suitable for structural applications.
• Low-calcium fly ash based geo-polymer concrete offers several economical benefits over
Ordinary concrete since the cost of fly ash only fraction of cement . More over the bulk cost of
Sodium silicate and sodium hydroxide solids are smaller than the current price of portland
Cement.
REFERENCES
• Research report on Development and properties of low-calcium fly ash-based geo-polymer
concrete by D.Hardjito and B.V.Rangan.
• IS 456-2000 indian standard plane and reinforced concrete code of practices, bureau of indian
Standards, New Delhi.
• Fly ash and its applications as a building material, a booklet published by Govt. of india,
National Buildings Organization and UN regional housing center ECAFE, nirman bhavan ,
New delhi.
• Malhotra. V.M. “High performance HVFA concrete. A solution to the infrastructural needs of
india” , the indian concrete journal, feb 2002,pp.103-107.
• Indian standard mix design procedures for plane and reinforced concrete code of practice, IS
10232: 1982, bureau of indian standards, new delhi.
• Shetty.M.S.,’concrete technology’ Dhanapat rai publications, new delhi, 2002.
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