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SUSTAINABLE SOLUTIONS IN CONCRETE INDUSTRY
GSAS Sponsored Seminar / Workshop MEETING TODAY’S DEMANDS BY ADOPTING THE LOW CARBON CONCRETE REVOLUTION Christopher Stanley, Technical Director, Unibeton Qatar National Convention Centre, Doha – Qatar 24th May 2014
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What is Sustainability?
Producing great structures that last Using least possible energy both during construction and remaining service life. Embedded CO2 and operational CO2 need to be considered Eliminating future maintenance costs. 120 year design life can now be extended to 400 years. Leaving a better world to our children Better durability: against chlorides, sulphates, ASR, acid attack Better colour – high light reflectance
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Sustainability Development
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Sustainability Development
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Sustainability Development
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What is Low Carbon concrete?
Low Carbon Concrete is a GREEN concrete. That does not mean concrete that has not yet hardened, or is coloured with green pigment, but in the context of this presentation green concrete is taken to mean environmentally friendly concrete. • This means concrete that uses less energy in its production & produces less carbon dioxide than normal traditional concrete.
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Where does the Carbon Dioxide come from in concrete?
The main ingredient in cement is Limestone (Calcium Carbonate CaCO3 ) During manufacture the ingredients are heated to about 1200oC During this process the Carbon Dioxide is driven off : CaCO3 = CaO + CO2 1kg of cement releases 700gms -1kg of Carbon Dioxide into the atmosphere during its manufacture
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Low Carbon Green concrete
Most of CO2 in concrete is from the cement manufacturing process (1 kg of cement produces about 1 kg of CO2 or 5 m3 of CO2) Low Carbon Green concrete makes more effective use of cement giving a reduced carbon footprint and therefore protects the environment. Low carbon green concrete = effective use of cement means better not lower quality
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CO2 and production energy
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CO2 Emissions from industry
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3.5kg of cement produces enough CO2 to fill this balloon
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A typical 40N concrete mix generates 100 balloons of CO2 per cubic metre of concrete
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Calculation of CO2 for a Typical 40MPa Concrete
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If some of the cement in the mix was replaced with GGBFS
GGBFS (say 70%) = 294 kg x = 32 kg of CO2/m3 126 kg of cement x = kg CO2/m3 = 32 kg CO2/m kg CO2/m3 = kg CO2/m3 REPRESENTING A REDUCTION OF kg CO2/m3
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A 25% replacement of Portland Cement with PFA
25% PFA = 105 kg x 0.06 = 6.3 kg of CO2/m3 + 315 kg of cement x = kg CO2/m3 Total of kg, or a saving of kg of CO2 replacing 25% of the cement with PFA
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Low Carbon Green concrete
Cement production accounts for 6% of all CO2 emission which is claimed to be one of the factors influencing global warming. In 2013 Qatar was the highest cement consumer per capita in the world. 1 Qatar tonnes/year/capita 2 UAE tonnes/year/capita 3 Kuwait tonnes/year/capita 8 Saudi Arabia 1.4 tonnes/year/capita 40 Oman below 0.6 tonnes/year/capita
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LOW CARBON GREEN CONCRETE OPTIONS
Highly optimized mix design Self-compacting concrete Ground granulated blastfurnace slag Pulverised fly ash. (Pfa) Portland limestone cement Rice husk ash cement Rice husk cement Cement free concrete Concrete wood Low cost construction
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Optimized Concrete Means Value Engineering
Better Performance Enhanced cohesion workability, finishability and consistency Reduced shrinkage / creep. Lower compressive strength SD Durability - Increased service life of concrete Greater Value Minimizes amount of steel needed Higher MOE can allow reduced section thickness weight Optimizes use of available materials Greener LEED Contributes to Certification points Reduced carbon footprint Affordable “green” alternative
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Mix optimization; A New Approach
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Mix optimization
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MIX OPTIMIZATION The basis for optimization is that the small particles can fill the space between the large ones to minimize the void content which creates maximum stability.
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Particle packing – voids content (1)
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Particle packing – voids content (2)
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Aggregates – natural angle of repose
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Slump test - 20mm aggregate
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Slump test – Dune sand
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Aggregate proportions affect the properties of concrete
The slump of the concrete and its flow are a function of the angle of repose, shape & the quantity of the predominant size of the aggregate in the mix. Use of more fine aggregate, because of the smaller angle of repose, gives higher slump & flow. But the optimum proportions of coarse & fine aggregate are critical to the properties of both fresh & hardened concrete.
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“Particle-Packing Optimization” to meet requirements of plastic and hardened properties”
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Typical spread of an optimized mix – note the aggregate distribution & that it does not bleed
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Life Cycle Analysis
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Heat of hydration The heat of hydration of optimized modified concrete is significantly lower than traditional concrete This results in a lower temperature rise in large concrete pours which is a distinct advantage. The peak temperature rise can be reduced by up to about 14oC.
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A typical 40N optmized mix produces only 27 balloons of CO2 per cubic metre of concrete
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Low Carbon Optimized Green concrete gives value engineering
Better performance • Enhanced workability,finishability & consistency • Reduced creep & shrinkage • Increased service life Greater value • Minimises amount of reinforcement • Higher Modulus of Elasticity – reduced thickness • Ease of compaction – less labour Greener • Contribution towards LEED Certification points • Upto two ESTIDAMA points in UAE • Reduced Carbon Footprint • Affordable Green construction
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Embodied GHG - Estidama
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Concrete Mix Design
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VERY GREEN CONCRETE Unibeton is now developing a technology to make very green concrete, sometimes even without Portland Cement, using a special process. This concrete will produce only about 7 balloons of CO2 per cubic metre. The concrete sets and hardens like Ordinary Portland Cement. It has a one day strength of about 22MPa and 28day strengths of 60 – 75 Mpa can be achieved.
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No-cement concrete By 2050 global use of cement likely to be 5,000Mt (steel will be 8,000Mt). No-cement concrete could be 1/3rd so 1,666Mt or 4,700Mm3 of cement-free concrete. Highly likely that PFA and other byproduct pozzolans will increasingly make “greener” concrete and reduce embedded CO.
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Our solution Use a cement replacement (binder) based on the activation of ground granulated blast furnace slag (GGBS) and pulverised fuel ash (PFA) byproducts. Both are widely available and relatively inexpensive. GGBS and PFA must be activated to produce a binder. There are recently invented new types of activators. Resulting binder used in much the same way as Portland Cement without the carbon legacy.
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No Cement Concrete The technical advantages
Sets chemically with very low heat of hydration Vast areas poured without joints- increased productivity No early-age thermal cracking – take out reinforcement 30 MPa in 7 days, >50 MPa at 90 days, and >70MPa at 365 days Greater dimensional stability – low shrinkage and creep Resistant to chloride, sulphates and acids Maintenance-free. Much extended service life Complies with performance based standards such as ASTM C1157 Low Heat Concrete category
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VERY GREEN CONCRETE
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Green Pre-stressed Concrete 64MPa at 28days
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Green Pre-stressed Concrete Advantages
Cost similar to most concrete used in GCC containing Slag or PFA Green alternative only 7% of carbon footprint of traditional OPC concrete Significant Carbon Credits due to reduction of CO2 emissions Track record of use in pre-tensioned pre-stressed concrete in USA
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Green Pre-stressed Concrete Advantages
Green cement free concrete can currently be produced in strengths ranging from 20MPa to over 75MPa Current pre-stressed production normally calls for a concrete strength of 24MPa at the time the tendons are released and with a final strength of in excess of 35MPa. The early strength gain can be adjusted to suit the production process but is normally in the region of 24hr-48hr before tendon release.
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Green Pre-stressed Concrete
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Green Pre-stressed Concrete
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Green Pre-stressed Concrete
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Green Pre-stressed Concrete
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THAT IS EQUIVALENT IN TERMS OF REDUCED CO2 TO:
THREE MILLION TONNES OF GGBFS WILL PRODUCE 7.8 MILLION TONNES OF GREEN LOW-CARBON CONCRETE. THAT IS EQUIVALENT IN TERMS OF REDUCED CO2 TO: TAKING 800,000 CARS OFF THE ROAD 85,000 SPACE SHUTTLE LAUNCHES SAVING 2.5 MILLION TONNES OF CO2 BY NOT USING PORTLAND CEMENT SAVING CO2 NEEDED TO SUPPLY 3.8 MILLION HOUSES WITH HOT WATER
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Doing more with less Take out crack control reinforcement (saving up to 30% steel) Reduce binder content using performancebased specifications to achieve C40, C50, C60 … concretes Reduce concrete cover by 10mm by Q C measures on site. Use Eurocode 2:1992:1-1; 2004 Clause Sustainability and durability are compatible. We can use the enhanced properties of concrete to avoid over-design
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Environmental advantages
Reduced energy consumption Reduced CO2 emissions Diversion of industrial by-products from landfilling Lower water consumption Reduced steel use
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Recently finished 10,000 sq ft (1,000 sqm) warehouse – Cambridge, Laid in one day with no joints.
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Large Scale Field Trials
This large scale field trial was conducted for Crossrail in East London. It marked the first occasion that No Cement Concrete concrete was pumped.
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FOR EVERY m3 OF NO CEMENT CONCRETE, 281 KG OF EMBEDDED CO2 ARE REDUCED
THE EMPIRE STATE BUILDING WAS CONSTRUCTED FROM 47,400 m3 OF CONRETE. IF IT HAD BEEN CONSTRUCTED FROM NO CEMENT CONCRETE = A SAVING OF 13,319 TONNES OF CO2 IT TAKES 1.87 TONNES OF CO2 TO FLY ONE PASSENGER FROM LONDON TO QATAR OR 7000 RETURN FLIGHTS FROM LONDON TO QATAR WOULD BE THE SAVINGS IN CO2 BY BUILDING THE EMPIRE STATE BUILDING IN CEMENT FREE CONCRETE RATHER THAN TRADITIONAL CONCRETE.
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Advantages of using No Cement Concrete
Substantially reduced CO2 emissions and energy use in the construction sector Utilisation of by-products which would be otherwise land filled (certain geographical locations, India, China etc;) Improved durability because: Much decreased capillary porosity (prevents ingress of aggressive chemicals, including chlorides, acids and sulphates, into concrete) Much denser cement-aggregate interface (reduces permeability) Much better bond to steel reinforcement
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Concrete Spring!
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