Renewable ENERGY

Abu Dhabi, UAE After a series of delays in project development, Masdar City,

Masdar Pushes Back Completion Date

$22 billion pioneering clean technology project, has been delayed by up to 10 years.

In the revised schedule, Masdar’s 1 million m² phase 1 has been pushed back by about two years to 2015. A completion date of 2020 to 2025 has replaced the original date of 2016.

Among key changes – although the goal of being 100% powered by renewable energy remains – “the world’s first zero-carbon, zero-waste city” is now set to purchase clean energy from outside rather than rely entirely on its on-site facilities.

In accordance with national development plans of various countries around the world set itself to achieve the following targets:

• Government of Canada will work in 2015 10 percent of electricity in the country would come from wind,
  
• Germany 2020 plans to 20 percent electricity to make wind power,
  
• The European Union set itself the objective: At the end of 2010 to increase wind power generation up to 40 thousand  MW 2020′s – up to 180 thousands MW,
• Spain, 2011 the construction of wind turbines with a capacity reach 20 thousand MW
• India 2012 wind power capacity will increase four-fold compared with 2005‘s,
  
• New Zealand is planning to wind power plants produce 20 per cent. electricity;
• Great Britain in 2010 from the wind will be 10 percent electricity,
• Egypt 2010 to construct a 850 MW of wind generators,
  
• Japan in 2010-2011 increase its wind power capacity by 3000 MW.

The total wind generating capacity worldwide, MW

According to the data of Joint German Bremen and Bremerhaven Ports Authority, they are currently focusing on the service of the new design of wind farms at sea. North Sea has a number of wind farms now. Thus, approximately 25 percent of investments are assigned for the wind park service facilities. In Germany now three ports – Emden, Kukshafen and Bremen-Bremerhaven are struggling in which of these ports wind farms service infrastructure will be installed.

Recently, Bremen-Bremerhaven has signed a contract with the German energy concern. It will then be allowed to use part of the Bremerhaven container terminal. There the wind power plant maintenance services will be equipped.

It is likely that wind power service for 10 years will be a real challenge for logistics professionals – not only in Germany but also in Great Britain and Holland. This is a topical issue for the Baltic countries. In the near future wind farms should be set up in the Baltic Sea. Then their base of support will be set up on the coast.

National Renewable Energy Laboratory (NREL) USA

NREL main research area is solar energy, wind energy and biofuels. Attention is also dedicated to heat-efficient building materials and electric cars. Currently, a very modern building is being built in the laboratory area. It will not only secure energy for itself, but also provide.New ultra-thin photovoltaic films are being developed and tested in Solar Energy Division.

In 2009 the company””””s professionals have managed to patent the technology, enabling a smooth transfer of information. Let us analyze what it means. Circulation of information is created by adding electric communication wires. In the past having started a signal at one point, it did not go far because of the catch of transformers or other equipment.

To better understand the information exchange, let us provide an example: imagine three rivers, which flow in at one place. Let’s check each of the waters in different colors. Having mixed the river waters of different colors, the color becomes dark, but after taking a test and measuring its components we can determine the extent of each color in this mixture. It is the same with grid – at each individual point in the network one can measure how much energy comes from whatever source, for example, how much wind power, solar energy, nuclear or thermal energy is produced. This energy is called “selected”.

Power Tagging Technologies began work understanding the need to create a network map managing energy demand. After creating such a network, there is the possibility, if necessary, to switch off and on certain equipment to avoid excessive electricity demand. According to energy experts, it allows not to build additional power plants.

Given the fact that nowadays to build one coal-fired power plant in U.S. costs 1, 8 billion U.S. dollars, the economic positive impact of the map of the grid on the country is incontrovertible. This network map is a great “smart network” model.

Knowing the fact that there is worldwide promotion of renewable energy development, there is no doubt that the term “Smart Networks” will feature more often.

U.S. utility company “Domination” last year invested 3 million dollars in the new entrant””””s Power Tagging Technologies.

Please note that in February 2009 U.S. President Barrack Obama signed a 787 billion dollar economic stimulus package. A significant part of it is intended to be used for development of renewable energy sources.

Researchers from the University of Zaragoza (UNIZAR) have calculated the energy and economic potential of urban solid waste, sludge from water treatment plants and livestock slurry for generating electricity in Spain. These residues are alternative sources of renewable energy, which are more environmentally friendly and, in the case of solid urban waste, more cost effective.

Using waste to generate electricity has economic and environmental advantages. “It gives added value to waste, because it can be seen as a type of fuel with zero cost, or even a negative cost if taxes are paid to collect it,” says Norberto Fueyo, lead author of the study and a researcher at the Fluid Mechanics Group of the UNIZAR.

According to the researcher, generating electricity from waste avoids “pernicious” impacts. Waste in landfill sites releases methane and other polluting gases, so incinerating solid urban waste will reduce the volume of waste that reaches the landfill sites in the first places, as well as the implicit risks of landfills themselves (possible emission of methane into the atmosphere).

wsci

The study, published in the latest issue of the journal Renewable Energy, has shown that waste in Spain could generate between 8.13 and 20.95 TWh (terawatt hours). “This electricity generation was 7.2% of electricity demand in 2008,” says Fueyo.

The researchers stress that the amount of methane generated from different kinds of residues is equivalent to 7.6% of gas consumption in 2008.

In terms of the economic cost, “solid urban waste is the most cost-effective,” according to the researcher, because local authorities carry out the waste collection and local inhabitants pay for it. Since the waste is transported to large landfill sites or waste treatment plants, installing electricity generation systems “could take advantage of economies of scale due to the large volumes involved.”

Cost depends on the heat generated

According to the study, incineration of waste and degasification of landfill sites are the electricity generation technologies with lowest financial cost. Producing electric energy through anaerobic digestion (a biological process in which organic matter decomposes into biogas in the absence of oxygen and through the action of a group of specific bacteria) is much more expensive.

“However, its profitability relies on being able to get value out of the heat generated during the process,” explains Fueyo, who says this technique is “not competitive, but makes use of the heat to offset the costs of generation.” However, the researchers point out that “directly applying this waste to agricultural land as fertiliser could contaminate groundwater with nitrates.”

In order to evaluate the potential and the cost of generating electricity, the researchers applied the methodology in municipal areas (in the case of solid urban waste and sludge from water treatment plants) and regional areas (for livestock slurry) throughout the whole of Spain.

The work shows that the centre and south of the Iberian Peninsula, the Balearic and Canary Islands have the “greatest interest” in putting technologies into place to use solid urban waste.

In terms of using water treatment plant sludge, the coastal areas of Galicia. Valencia and Alicante, as well as central and southern Spain, were also areas of interest. The study also shows that certain areas of Aragon, Castilla-La-Mancha, Castilla-y-León, Extremadura, Galicia and Andalusia “would be effective” for using livestock slurry.

The EU 20-20-20 package

The research into electricity generation comes in response to the European Union (EU) objective to fulfil the 20-20-20 package for the year 2020, in other words to substitute 20% of the total energy consumed in Spain for energy from renewable resources, reduce CO2 emissions by 20% in comparison with 1990 figures, increase biofuels used in transport by 10%, and achieve energy savings of 20%. “For Spain, each one of these targets alone is a challenge, which becomes much bigger when they are all taken together,” underscores the scientist.

Norberto Fueyo says the most problematic objective is that relating to increasing the amount of biofuels used in transport by 10%. “It is not achievable and is socially and environmentally questionable, because of the amount of land it requires and because it means using foodstuffs to produce fuel.”

Even if the figure of 10% of biofuels in transport is achieved, the expert says “there will need to be an increase of around 45% in the contribution of renewables (including hydroelectric energy) to electricity generation in order to achieve a figure of 20% of renewable energy within total consumption”. The scientist adds that, in order to achieve the objective, it will be “essential” to promote energy saving and efficiency “and consider all possible sources of renewable energy, including waste.”

The brain of any electronic device is the circuitry that operated the machine. Without the circuitry, the device is not even worth the cost of the plastic that it is made of. Any electronics device requires some kind of battery or it is nothing more than a paperweight. Recently, some new technology was created by scientists from the “University of Pennsylvania” that will no longer require a device to use a battery as the power can come from light-powered circuitry.

light powered circuitry

It is technology that can lead to incredible independence down the road. Imagine cell phones or laptops that never run out of power. To think that something that can literally fit on the edge of a pair of tweezers can actually create enough energy to run some of these devices is pretty amazing.

Another significant possibility is the actual creation of a simulated human brain. While everyone loves the Terminator movies, it is unlikely that anyone thinks that we would ever see something like that during our lifetime. This technology actually makes that a very real possibility.

In essence, the light source would serve as the electrons that normally power our brains. Data that is registered would literally be able to be processed at the speed of light to simulate the exact same functions as the human brain. The scientific and technology communities are sitting there with their mouths wide open in anticipation of what the future holds because of this tiny little light-powered circuit.

While the light-powered circuit still has a way to go before it can hold and generate the amount of power that would be needed to power an electrical device, let alone a simulated human brain, the hardest part has already been done. Now they have to refine their discovery and figure out how to get more power out of it so that it can realize its full potential.

new tech

Because of the sheer volume of discoveries that are announced on an almost daily basis, it is understandable how something can slip by and be perceived as no big deal. Make no mistake about it, a light-powered circuit is one of those discoveries that is a little more significant than a cell phone that has a solar panel on the back of it. This is a discovery that can literally change the world as we know it.

Masdar City – a living city that will provide the research and the test base for it”s own technologies. It is a unique place, not only because it will be a centre of innovation, product development and light manufacturing in the fields of renewable energy and sustainable technologies but also because it aims to be a zero carbon, zero waste and a 100% renewable energy-powered community. A computer generated image showing the interior courtyard of an office building in Masdar City.

These unprecedented sustainability targets mean that Masdar City will require the most cutting-edge technologies and solutions in the areas of energy and water conservation, waste management, smart grid technologies, transportation and renewable energy generation. As such, Masdar City will be a first-of-a-kind test bed for the large-scale trial and deployment of early-stage technologies and practices. Plus, in moving towards these targets, Masdar City will itself demonstrate that much higher levels of sustainability than previously imagined are achievable, even while providing a high-quality living and work environment.

masdar

The city will be home to leading multinational companies in the Clean tech sector, as well as small- and medium-sized enterprises and entrepreneurial start-ups. Companies will set up R&D labs, global headquarters and regional sales offices in the city to take advantage of the many cluster advantages, including potential access to funding and emerging technologies, and a large pool of researchers and other experts in the field.

Both General Electric and BASF will, amongst others, have operations in the city, while the International Renewable Energy Agency (IRENA) – an inter-governmental organisation dedicated to promoting the widespread adoption and sustainable use of all forms of renewable energy – will locate its headquarters at Masdar City. The Masdar Institute of Science and Technology, developed in cooperation with the Massachusetts Institute of Technology, will be at the heart of the city’s R&D activities.

Masdar City is a living city that will provide the research and the test base for its own technologies. It is a unique place, not only because it will be a centre of innovation, product development and light manufacturing in the fields of renewable energy and sustainable technologies but also because it aims to be a zero carbon, zero waste and a 100% renewable energy-powered community. A computer generated image showing the interior courtyard of an office building in Masdar City.

These unprecedented sustainability targets mean that Masdar City will require the most cutting-edge technologies and solutions in the areas of energy and water conservation, waste management, smart grid technologies, transportation and renewable energy generation. As such, Masdar City will be a first-of-a-kind test bed for the large-scale trial and deployment of early-stage technologies and practices. Plus, in moving towards these targets, Masdar City will itself demonstrate that much higher levels of sustainability than previously imagined are achievable, even while providing a high-quality living and work environment.

masdar2

The city will be home to leading multinational companies in the Clean tech sector, as well as small- and medium-sized enterprises and entrepreneurial start-ups. Companies will set up R&D labs, global headquarters and regional sales offices in the city to take advantage of the many cluster advantages, including potential access to funding and emerging technologies, and a large pool of researchers and other experts in the field.

Both General Electric and BASF will, amongst others, have operations in the city, while the International Renewable Energy Agency (IRENA) – an inter-governmental organisation dedicated to promoting the widespread adoption and sustainable use of all forms of renewable energy – will locate its headquarters at Masdar City. The Masdar Institute of Science and Technology, developed in cooperation with the Massachusetts Institute of Technology, will be at the heart of the city’s R&D activities.