How Much CO2 Gets Emitted to Build a Wind Turbine?
August 16, 2014 by
The ONLY justification for wind power – the massive subsidies upon which it entirely depends (see our post here); spiralling power prices (see our post here); and the suffering caused to neighbours by incessant low-frequency noise and infrasound (see our post here) – is the claim that it reduces CO2 emissions in the electricity sector.
STT has pointed out – just once or twice – that that claim is nothing more than a central, endlessly repeated lie. Because wind power fails to deliver at all hundreds of times each year, 100% of its capacity has to be backed up 100% of the time by fossil fuel generation sources – which run constantly in the background to balance the grid and prevent blackouts when wind power output collapses – as it does on a routine, but unpredictable, basis (see our posts here and here and here and here and here and here and here and here).
But – even before the blades start spinning – the average wind farm clocks up thousands of tonnes of CO2 emissions: “embedded” in thousands of tonnes of steel and concrete. So, every wind farm starts with its CO2 abatement ledger in the negative. Here’s Andy’s Rant with a breakdown of just how much CO2 goes to build a giant fan.
So what’s the carbon foot print of a wind turbine with 45 tons of rebar & 481m3 of concrete?
Andy’s Rant
4 August 2014
Its carbon footprint is massive – try 241.85 tons of CO2.
Here’s the breakdown of the CO2 numbers.
To create a 1,000 Kg of pig iron, you start with 1,800 Kg of iron ore, 900 Kg of coking coal 450 Kg of limestone. The blast furnace consumes 4,500 Kg of air. The temperature at the core of the blast furnace reaches nearly 1,600 degrees C (about 3,000 degrees F).
The pig iron is then transferred to the basic oxygen furnace to make steel.
1,350 Kg of CO2 is emitted per 1,000 Kg pig iron produced.
A further 1,460 Kg CO2 is emitted per 1,000 Kg of Steel produced so all up 2,810 Kg CO2 is emitted.
45 tons of rebar (steel) are required so that equals 126.45 tons of CO2 are emitted.
To create a 1,000 Kg of Portland cement, calcium carbonate (60%), silicon (20%), aluminium (10%), iron (10%) and very small amounts of other ingredients are heated in a large kiln to over 1,500 degrees C to convert the raw materials into clinker. The clinker is then interground with other ingredients to produce the final cement product. When cement is mixed with water, sand and gravel forms the rock-like mass know as concrete.
An average of 927 Kg of CO2 is emitted per 1,000 Kg of Portland cement. On average, concrete has 10% cement, with the balance being gravel (41%), sand (25%), water (18%) and air (6%). One cubic metre of concrete weighs approx. 2,400 Kg so approx. 240 Kg of CO2 is emitted for every cubic metre.
481m3 of concrete are required so that equals 115.4 tons of CO2 are emitted.
Now I have not included the emissions of the mining of the raw materials or the transportation of the fabricated materials to the turbine site so the emission calculation above would be on the low end at best.
Extra stats about wind turbines you may not know about:
The average towering wind turbine being installed around beautiful Australia right now is over 80 metres in height (nearly the same height as the pylons on the Sydney Harbour Bridge). The rotor assembly for one turbine – that’s the blades and hub – weighs over 22,000 Kg and the nacelle, which contains the generator components, weighs over 52,000 Kg.
All this stands on a concrete base constructed from 45,000 Kg of reinforcing rebar which also contains over 481 cubic metres of concrete (that’s over 481,000 litres of concrete – about 20% of the volume of an Olympic swimming pool).
Each turbine blade is made of glass fibre reinforced plastics, (GRP), i.e. glass fibre reinforced polyester or epoxy and on average each turbine blade weighs around 7,000 Kg each.
Each turbine has three blades so there’s 21,000 Kgs of GRP and each blade can be as long as 50 metres.
A typical wind farm of 20 turbines can extend over 101 hectares of land (1.01 Km2).
Each and every wind turbine has a magnet made of a metal called neodymium. There are 2,500 Kg of it in each of the behemoths that have just gone up around Australia.
The mining and refining of neodymium is so dirty and toxic – involving repeated boiling in acid, with radioactive thorium as a waste product – that only one country does it – China. (See our posts here and here).
All this for an intermittent highly unreliable energy source.
And I haven’t even considered the manufacture of the thousands of pylons and tens of thousands of kilometres of transmission wire needed to get the power to the grid. And what about the land space needed to house thousands of these bird chomping death machines?
You see, renewables like wind turbines will incur far more carbon dioxide emissions in their manufacture and installation than what their operational life will ever save.
Maybe it’s just me, but doesn’t the “cure” of using wind turbines sound worse than the problem? A bit like amputating your leg to “cure” your in-growing toe nail?
Metal emission stats from page 25 from the 2006 IPCC Chapter 4 Metal Industry Emissions report.
Cement and concrete stats from page 6 & 7 from the 2012 NRMCA Concrete CO2 Fact Sheet.
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