Green cement: an industry revolution?

 

Cement produces more carbon dioxide than the whole of the aviation industry. But now there’s a variant that actually absorbs greenhouse gases.

The argument about which is the greener construction material, concrete or steel, could be about to take a new turn. UK scientists say they have discovered a way of producing cement which, instead of emitting carbon dioxide, absorbs it from the atmosphere. Given that cement accounts for about 5% of the world’s carbon dioxide emissions, more than the aviation industry, and that concrete production is set to grow 50% by 2020, the discovery could be the breakthrough of the decade in the construction industry.

The cement has been developed by Novacem, a spin-off company of Imperial College in London. It uses different raw materials to conventional Portland cement. According to Nikolaos Vlasopoulos, the company’s chief scientist, when they were developing the cement they wanted to cross the boundary and make a material that was carbon negative. “That was our goal from the outset,” he says.

Traditional Portland cement is made by heating limestone and clay in giant kilns at about 1,500ÞC to produce clinker. This is ground with gypsum to make cement. The International Energy Agency estimates that for every tonne of cement releases an average of 0.83 tonnes of CO2. About half of this is generated from the vast amounts of energy needed to heat the kilns and the other half is released in chemical reactions as the limestone decomposes.

According to Vlasopoulos there is little that can be done to reduce the CO2 emissions given off when clinker is produced. “Unless you have a way to capture it and encapsulate it, it’s going to be released into the atmosphere.”

However, instead of limestone, Novacem’s cement uses magnesium oxides. Vlasopoulos is coy about the exact technique – a patent is still pending – but says they have developed a way of converting magnesium silicates, which are abundantly available, into magnesium oxide, which is used as the raw material for the cement. The advantage of using magnesium oxide is that the production process requires lower temperatures – typically in the range of 650ÞC to 700ÞC – and it does not give off any carbon dioxide in the reaction.

Lower temperatures open up the possibility of decreasing the carbon footprint further by using biomass. Traditional cement production relies on a mix of fuels such as coke and coal, as well as used tyres, meat, bone meal and packaging waste. For the past decade cement makers have been working on ways to reduce their energy consumption. “There has been a move to switch to lower carbon content fuels,” says Vlasopoulos. “The problem is that they cannot sustain the temperatures as easily as when you use coke or coal to fire the kilns. If you use lower temperatures we can be much more flexible in the types of fuel we use.”

Of course this still means that carbon dioxide is produced, but Novacem’s cement absorbs carbon dioxide when it hardens; Portland cement does this too but Novacem’s cement absorbs it in much greater amounts. Portland cement soaks up anywhere between 0.2 and 0.5 tonnes, which, taking into account the production process, leaves an overall carbon footprint of between 0.3 and 0.6 tonnes. Vlasopoulos says production of a tonne of his cement generates 0.4 tonnes of CO2 but absorbs 1.1 tonnes when it hardens meaning on balance it absorbs 0.7 tonnes of CO2 from the atmosphere. This compares favourably with steel which produces an average 1.7 tonnes of CO2 for every tonne produced.

The big question of course is when will the cement be available? Work on developing full-scale production facilities is now under way and the company is working with Rio Tinto Minerals on how best to get hold of magnesium silicate, but, says Vlasopoulos, it will be three to five years before it is commercially available. “It needs some time to fall into place; we need to build production plants and get the market on board.”

And there’s more to come. Vlasopoulos and his team are also working on a way to recycle its magnesium oxide cement. “Normally with concrete you break it up and recover it as aggregate and use it instead of sand and gravel. We propose recycling it to make cement again. It’s not something that will happen now as you need a stock of buildings to do it with but in the long term this is our goal.”

 

Concrete facts

 

· Global cement production accounts for about 2 billion tonnes of CO2 every year – that’s 5% of all CO2 emissions

· Global cement production in 2007 = 2,690 million tonnes

· Global cement production by 2012 = 3,370 million tonnes

· Chinese cement production in 2007 = 1,240 million tonnes, a threefold increase from 1995. It is predicted that by 2012 it will produce over half of global output

· The EU produced 310 million tonnes of cement in 2007

 

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Eco-Housing in the UK

 

window.google_render_ad(); Eco-housing, or houses built in accordance with the principles of sustainable development, which use resources and technologies that capitalise on renewability, are a fast-developing industry in the UK be they individual projects, or whole estates, designed to accommodate and create a new community.

Individual or one-off projects, such as those detailed on other pages on this website, For example yurts, straw-bale houses or dwellings built underground, might reflect the owner or architects unique vision, or maybe use one material pre-dominantly. But how to incorporate ecological design and 'green thinking' into projects and buildings that can appeal to a wider group of people - those who like the idea, but don't necessarily have the time or money to invest in such a project? How can eco-housing live alongside or even replace traditional housing units and estates in the UK?

This article will look at 3 examples of larger ecologically-built projects.

 

The Bed ZED Project, London

 

The Bed ZED Project, or Beddington Zero Energy Development, is the UK's largest carbon-neutral eco-community in the UK. It was built in 2002 in Wallington, Surrey, Within the London Borough of Sutton, and comprises of 82 residential homes. The Project was developed by the Peabody Trust, a social housing initiative in London, that aims to fight poverty within the capital. The intention with this project, built in partnership with both an architect and an environmental consultancy firm, was to create a housing project that incorporates new approaches to energy conservation and sustainability, and also to build a thriving community to live within it.

window.google_render_ad(); The houses are equipped with key features, both technological and common sense - for example, designed in south facing terraces to maximise solar heat gain, that utilise renewable, and conservable, energy. A small-scale combined heat and power plant on site, powered by wood off-cuts, provides most of the energy to the estate. All buildings have a thick insulation jacket, made from recycled materials. The project has a legally-binding green transport plan, incorporating a car pool system for residents, great public transport links, and is linked in to a cycling network. For these, and many more social and environmental initiatives and technologies, Bed ZED has won many national and International awards for sustainability, design, Innovation and more. It is an inspiring achievement on a local and social level.