With
carbon emissions from traditional energy sources contributing heavily on the global
warming effect all around the world and the demand for energy growing rapidly,
the energy crisis is real. The demand for energy will soon be greater than
supply and we all will have a problem. In the past, renewable energy projects
proved difficult to sustain long term due to operational costs, so the costs
were passed on to consumers. Now, thanks to the European Union’s agreed 2020
renewable energy targets, governments are taking the matter more seriously and
setting aside larger budgets to support cutting edge green energy projects.
On
the 29th January, 2009, the European Commission proposed spending Euro 3.5
billion on carbon capture and storage investments and a further Euro 500
million is to be used on renewable energy projects, specifically offshore wind
projects. President Obama’s gargantuan economic stimulus also has green
alternative energy production at its heart, with the United States pushing
solar energy production hard in the coming years.
Hovever,
operational cost still remains a major bugbear for institutions
researching alternative energy sources, but fortunately some technological
breakthroughs are showing signs that cost may not be an issue for too much
longer.
1.
Offshore Wind Farms
The humble wind turbine has been around for some time. Travel across Europe and you are bound to see several wind farms along the way. Traditionally the same design and technology used on land has been used in offshore wind turbines; however, these designs were not sufficiently durable for the harsh conditions of the sea. This equated to high maintenance costs and an expensive alternative energy source.
The humble wind turbine has been around for some time. Travel across Europe and you are bound to see several wind farms along the way. Traditionally the same design and technology used on land has been used in offshore wind turbines; however, these designs were not sufficiently durable for the harsh conditions of the sea. This equated to high maintenance costs and an expensive alternative energy source.
Fortunately,
the tides are about to change. Areva, a French energy company, recently
announced that they were about to launch what is perceived to be the toughest
wind turbine ever built. Designed specifically to be deployed in remote
offshore wind farms where harsh climatic conditions are prevalent, Areva claim
that operational costs will be significantly reduced as the simplified design
of the Multibrid M5000 means that they are easier to install and require fewer
maintenance visits.
These giant wind turbines will stand approximately 90 metres above the water and will have a blade diameter of around 120 metres. They should prove highly efficient as well: each of the 5MW turbines is said to be able to generate enough electricity to supply 5,000 homes.
These giant wind turbines will stand approximately 90 metres above the water and will have a blade diameter of around 120 metres. They should prove highly efficient as well: each of the 5MW turbines is said to be able to generate enough electricity to supply 5,000 homes.
With
the launch project off the coast of Germany imminent, we won’t have long to
wait before we see proof that large scale offshore wind farms are a truly
viable means of cheap energy production.
2.
Energy from Waste
The debate around whether energy from waste is a good alternative source of energy has been ongoing for many years. The leading arguments against this technology have been the potential risk to health from the fumes produced during the conversion process and that the production of waste undermines the recycling initiative.
The debate around whether energy from waste is a good alternative source of energy has been ongoing for many years. The leading arguments against this technology have been the potential risk to health from the fumes produced during the conversion process and that the production of waste undermines the recycling initiative.
But
the harsh reality is that waste will always be produced, even when recycling
meets government targets. Is it not better to use the waste for energy
production than for it to lie in landfills? As for the risk to health, there is
no scientific evidence to prove that burning rubbish leads to ill health.
The
proof of how green and cost efficient this energy source can be has been proven
by the UK’s first waste gasification plant built on the Isle of Wight. This
small, community sized plant is said to be able to generate 2.3MW of energy
from the 30,000 tonnes of residual waste not being recycled. This should be
enough to provide around 3,000 homes with electricity.
Energos, the Norwegian company building the plant, use a technology designed to minimise emissions when converting waste residue into steam, making it environmentally friendly while also addressing the costly landfill problem. Clearly we should still be reducing, reusing and recycling, but where there is waste there is also an opportunity to create clean energy and minimise the use of landfill.
Energos, the Norwegian company building the plant, use a technology designed to minimise emissions when converting waste residue into steam, making it environmentally friendly while also addressing the costly landfill problem. Clearly we should still be reducing, reusing and recycling, but where there is waste there is also an opportunity to create clean energy and minimise the use of landfill.
3.
Marine Energy: Wave and Tidal Stream
It is well known that being able to harness wave energy is one of the most sustainable and cleanest sources of renewable energy available. And as long as there are oceans and seas, there will always be waves and tides from which energy can be captured and converted.
It is well known that being able to harness wave energy is one of the most sustainable and cleanest sources of renewable energy available. And as long as there are oceans and seas, there will always be waves and tides from which energy can be captured and converted.
Even
though the planet’s oceans offer massive potential in terms of clean energy,
there have been major challenges in developing this elusive technology. One of
the biggest problems has been the requirement to locate large facilities on
rugged but beautiful coastlines, which is often passionately opposed by locals
who would rather not have such an eyesore. This is further compounded by the
fact that these power plants need exposure to consistent and powerful swells,
which typically means building a plant in an unspoilt area. On top of this, the
equipment has to be able to withstand constant and powerful ocean conditions.
SeaGen,
the first commercial scale tidal stream turbine developed by Marine Current
Turbines, seems to have overcome these obstacles and has a turbine installed
and finally operating at full capacity in Strangford Lough, Northern Ireland.
Previously the maximum output of a tidal stream system was 300kW, achieved by
their earlier SeaFlow system in 2004. SeaGen has out-performed this by
achieving a 1.2MW output, said to be able to provide enough electricity for
1,000 homes.
The Pelamis wave energy system is another ingenious example of harnessing energy from the ocean. These mechanical snakes can be placed in open ocean where the rising and dropping motion of passing swells are used to generate clean electricity, which is then sent back to the mainland via submarine cable. This relatively new system gets around the problem of visually spoiling coastlines as they are located a distance offshore. The northern Portuguese town of Aguçadoura was the first to install a commercial-scale wave power station using the Pelamis system, where it produces enough clean electricity to power 1,000 homes.
The Pelamis wave energy system is another ingenious example of harnessing energy from the ocean. These mechanical snakes can be placed in open ocean where the rising and dropping motion of passing swells are used to generate clean electricity, which is then sent back to the mainland via submarine cable. This relatively new system gets around the problem of visually spoiling coastlines as they are located a distance offshore. The northern Portuguese town of Aguçadoura was the first to install a commercial-scale wave power station using the Pelamis system, where it produces enough clean electricity to power 1,000 homes.
4.
Geothermal Energy Sources
Geothermal power generation was first successfully tested in 1904. Let that sink in for a while: clean, abundant energy has been a real possibility for over a century, yet it accounts for less than 1% of current power generation. That is quite frankly unacceptable when you take into account the environmental policies of many governments. This currently-available and widely tested method of power production is typically focused around tapping into steam vents, which is used to turn conventional turbines. However, there are also more experimental cyclic designs called Enchanced Geothermal Systems, where cold water is reintroduced through porous rock, then heated and converted to steam.
Geothermal power generation was first successfully tested in 1904. Let that sink in for a while: clean, abundant energy has been a real possibility for over a century, yet it accounts for less than 1% of current power generation. That is quite frankly unacceptable when you take into account the environmental policies of many governments. This currently-available and widely tested method of power production is typically focused around tapping into steam vents, which is used to turn conventional turbines. However, there are also more experimental cyclic designs called Enchanced Geothermal Systems, where cold water is reintroduced through porous rock, then heated and converted to steam.
In
the US alone, those boffins at MIT estimate [PDF] that geothermal has the
potential to generate an impressive 100 gigawatts of electricity or more with
just $1 billion investment, but unless the government decides to step up the
pace it won’t be possible until approximately 2050. The USA is currently the
largest producer of geothermal energy, which highlights how far the rest of the
world has to play catchup!
5.
Energy Saving Light Bulbs
They may be slightly more expensive but they are said to last up to 10 times longer. Amazingly, in January 2009, scientists at Cambridge University announced that they have developed an energy saving light bulb that can last up to 60 years! At around £2 / $4 per bulb, you certainly couldn’t get better value for money and they estimate that using these bulbs could cut lighting bills by up to 75%.
They may be slightly more expensive but they are said to last up to 10 times longer. Amazingly, in January 2009, scientists at Cambridge University announced that they have developed an energy saving light bulb that can last up to 60 years! At around £2 / $4 per bulb, you certainly couldn’t get better value for money and they estimate that using these bulbs could cut lighting bills by up to 75%.
It
is said that if energy saving light bulbs were installed in every home and
office in the UK, it could cut the entire country’s electricity consumption
used in lighting by up to 20% – a massive saving from something so small.
So even if you don’t want to install solar panels, heat pumps, small scale hydro or wind systems, you can still reduce your impact on climate change with very little effort or expense. Simply replace your old light bulbs with energy saving bulbs.
So even if you don’t want to install solar panels, heat pumps, small scale hydro or wind systems, you can still reduce your impact on climate change with very little effort or expense. Simply replace your old light bulbs with energy saving bulbs.
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