Let's make protecting the Environment 'Everyone's Duty'

ALTERNATIVE ENERGY, BIOPOLYMERS

We can say the present world economy is largely based on petrochemicals. Untill the beginning of the 19 the century global economy was largely based on carbohydrates. With the emergence of petroleum and its diverse set of products, world shifted progressively from carbohydrates to hydrocarbons.

Hydrocarbons are responsible for most of the present day pollution. Further petroleum reserves are gradually diminishing and one day they will be no more. The diiping reserves may even cause a raise in the price. There is thus a need to shift focus on alternatives to petroleum and its products.

Alternative forms of energy like wind, solar, and wave energy serve as alternatives to petroleum for fuel. Experts project that wind power will cader 20% of total electricity needs of America by 2030. Many efforts are in place to harness the wind, solar and wave energy across the globe.
Unlike the Petroleum based fuels, these are clean forms of energy and generate no pollution. Green house gas emmisiions can be reduced by increasing the share of these alternative forms of energy in the global energy usage. One day they might be the only option left behind. So its better we start workin on them seriously right from now.

Its not just in the area of fuel that we got to look into alternatives for petroleum. Many polymers are petroleum derivatives. About 7% of the petroleum reserves are used for polymer production. This can be replaced by Bio-Polymers. Biopolymers are obtained from raw materials produced by plants and animals or microbes. Unlike the hydrocarbon based polymers they are readily degradable under composting conditions (You should remember that normal conditions are not compostinditions. Special composting facilities are necessary. Hydrocarbon based polymers donot degrade under composting conditions).

Ofcorse there sre still many hurdles in the use of these alternatives.

Solar energy is very expensive at present.
Wind energy can be harnessed only in locations where sufficent wind speeds are available. Also proper infrastructure has to develop.
Coming to biopolymers they are not as efficient as synthetic polymers. The are either fragile, opaque, less tensile etc. So they can't be applied for the diverse apllications served by the synthetic polymers.

Efforts are in place and we will have the results in the years to come. Wish this happens at the earliest.

Biopolymers:

Biopolymers are obtained from natural sources like plants, microbes and animals. Plant biomass (carbohydrate) is a major source for the production of biopolymers. Countries like India and China that have abundant agricultural waste have a huge potential for the production of Biopolymers from plant biomass. (Crop residue in India is about 2 billion tonns). Its not wise to divert food material for the production of Biopolymers.

At present the share of biopolymers in the global polymer industry is 0.5% and is expected to grow to around 1.5 to 5%.

Yes, biopolymers are more environmental friendly. But to what extent are they good enough to replace the synthetic polymers. Certin properties of biopolymers act as barriers. Some biopolymers are brittle, some are thermally unstable, some are oaque. Example: PHB and PLA are extremely brittle. Combinations of various polymers can help in improving the properties.
(PHB: Poly Hydroxy Butyricacid. PLA: Poly Lactic Acid)
Apart from the above mentioned properties, some other market barriers include:

  • Price
  • Inadequate facilities for composting.
Major Application Platforms for Biodegradable Polymers are:
  • Packaging films.
  • Drug delivery Systems
  • Foams
  • Blends and composites
  • Integrated Bio-refinery

GREEN CEMENT !!!

Back when Stanford Professor Brent Constantz was 27 he created a high-tech cement that revolutionized bone fracture repair in hospitals worldwide. People who might have died from the complications of breaking their hips lived. Fractured wrists became good as new.

Now, 22 years later, he wants to repair the world.

Constantz says he has invented a green cement that could eliminate the huge amounts of carbon dioxide spewed into the atmosphere by the manufacturers of the everyday cement used in concrete for buildings, roadways and bridges.

His vision of eliminating a large source of the world's greenhouse CO{-2} has gained traction with both investors and environmentalists.

Already, venture capitalist Vinod Khosla is backing Constantz's company, the Calera Corp., which has a pilot factory in Moss Landing (Monterey County) churning out cement in small batches.

And Carl Pope, executive director of the Sierra Club, says it could be "a game changer" if Constantz can do it quickly, on a big scale and at a decent price.

"It changes the nature of the fight against global warming," said Pope, who has talked with Constantz about his work.

That might sound like hyperbole, but the reality is that for every ton of ordinary cement, known as Portland cement, a ton of air-polluting carbon dioxide is released during production. Worldwide, 2.5 billion tons of cement are manufactured each year, creating about 5 percent of the Earth's CO{-2} emissions.

When Constantz learned about the high CO{-2} levels, he thought he could do better. After all, the majority of his 60 patents have to do with medical cement.

He claims his new approach not only generates zero CO{-2} , but has an added benefit of reducing the amount of CO{-2} power plants emit by sequestering it inside the cement.

To make traditional cement, limestone is heated to more than 1,000 degrees Celsius, which turns it into lime - the principal ingredient in Portland cement - and CO{-2}, which is released into the air.

Constantz uses a different approach, the details of which remains secret pending publication of his patent.

At his pilot factory, a former magnesium hydroxide facility that made metal for World War II bombs, magnesium crunches underfoot as Constantz, wearing a pressed, blue button-down shirt with rumpled shorts and sandals, outlines how the process works.

He pointed to two enormous smokestacks billowing flue gases full of carbon dioxide next door at Dynegy, one of the West's biggest and cleanest power plants.

Constantz takes that exhaust gas and bubbles it through seawater pumped from across the highway. The chemical process creates the key ingredient for his green cement and allows him to sequester a half ton of carbon dioxide from the smokestacks in every ton of cement he makes.

Constantz believes his cement would tackle global warming on two fronts. It would eliminate the need to heat limestone, which releases CO{-2}. And harmful emissions can be siphoned away from power plants and locked into the cement.

The same process can also be used to make an alternative to aggregate - the sand and gravel - that makes up concrete and asphalt, which would sequester even more carbon dioxide from power plants.

"The beauty here is we're taking this old industrial polluting infrastructure and turning it into something that will save the environment," Constantz said.

On a per-person basis, the United States is the world's worst CO{-2} polluter from all sources. But according to the Netherlands Environmental Assessment Agency, China just surpassed the U.S. for total carbon dioxide emissions.

China is expected to produce 47 percent of the world's 2.5 billion tons of cement this year, Constantz said.

To power its new buildings and sustain its building boom, China constructs at least one coal-fired power plant a week. Each one belches out enough CO{-2} to cancel the benefits of every hybrid on U.S. roadways, said Constantz.

A CO{-2} molecule can travel from Beijing to San Francisco in less than a day through atmospheric circulation, he said. So even with California mandating that CO{-2} emissions fall to 1990 levels by 2020, a crisis remains.

"Carbon dioxide is a global problem, not a regional problem," he said.

As far as cost, Constantz estimates his cement would retail for $100 a ton versus roughly $110 for Portland.

The reason no one invented it before now, he said, is that people didn't truly understand the dangers of CO{-2} until less than a decade ago.

Skeptics question product

He has skeptics.

Portland cement has a track record of more than 100 years, and any new material would have to get incorporated into building codes, noted Rick Bohan, director of construction and manufacturing technology for the Portland Cement Association in Skokie, Ill.

And Tom Pyle, a Caltrans engineer who serves on the cement subgroup of Gov. Arnold Schwarzenegger's Climate Action Team, acknowledged that the technology is possible, but he still wants to examine Constantz's cement.

"We hope they have a carbon-reducing viable construction material," he said. "They need to show up with a bag of this so we can test it."

Constantz is confident he will prove himself. Initially, he proposes mixing his new invention with Portland cement to ease a conservative industry into a new product. Concrete bigwigs have invited him to speak about Calera cement at their annual World of Concrete in Las Vegas next February.

Power plant partnerships

Constantz envisions building cement factories next to power plants the world over. A team is scouting out U.S. locations. While Dynegy has supplied Constantz with some flue gas, it hasn't entered into a formal agreement.

"As we're looking into the future, we're very interested in technology that would help capture CO{-2} from the flue gases and turn it into a product that offers a benefit," said Dynegy spokesman David Byford.

It could be good for business. California has mandated emissions reductions. And Congress is working on legislation that would allow high polluters to buy credits from those with low emissions. Power plants would have a huge incentive to sequester their CO{-2} in cement.

But even if Constantz succeeds, the world would still need to do much more to fight CO{-2} emissions, said Chris Field, director of the department of global ecology at the Carnegie Institution for Science at Stanford. "It's a big, long complicated game," he said. "As we develop each new segment of the solution we need to embrace it and deploy it and work hard to develop the next segment of the solution."

Coral basis of idea

Big ideas can form in haphazard ways. The one for bone cement began during a televised football game, when Constantz read an osteoporosis article in the New England Journal of Medicine. Three weeks later, as he studied a coral reef, it occurred to him he could maybe synthesize coral skeletons in human bones.

His new cement mimics how coral reefs form, too. Coral uses the magnesium and calcium present in seawater to create carbonates much as he's using CO{-2} and seawater to make carbonate.

This latest invention took 18 months to conceive and execute. He feels it's one of the most important things he's ever done.

"Climate change is the largest challenge of our generation," he said.

Who is Brent Constantz?

Profession: An associate consulting professor in Stanford's department of geological and environmental sciences and founder of the Calera Corp. Created and sold three other companies - Norian Corp., Corazon Technologies Inc. and Skeletal Kinetics.

Education: UC Santa Barbara, bachelor's of science (1981); UC Santa Cruz, doctorate (1986)

Family: Married and father of four.

Pastime: Surfing and rock climbing.

Concrete facts about cement

2.5 billion tons of hydraulic cement is produced worldwide annually. Add sand and gravel and that makes more than 9,000 million cubic yards of concrete. That's more than enough concrete to pave an eight-lane highway from the Earth to the moon and back again - twice.

If you stayed on the planet, that same eight-lane highway would circle the Earth almost 40 times.

Source: Portland Cement Association

I SUCCEDED IN INSPIRING ONE BLOGGER !!!

Ghananadh is a friend of mine. He is also a blogger like me. He worked along with me in distributing the Paper C.D covers as a part of the "Avoid Polythene Campaign". May be its during that period that he started to think of doing his part to save the environment. Recently he posted an article to celebrate Ganesh Chathurthi in an eco-friendly way. I liked that post and i have posted it in my blog. I am happy that i'm successful in making him think for our environment.
Even he is working to make people avoid polythene. Im very happy that he is in one way extending the "Avoid Polythene Campaign". If this continues like this as a chain reaction definitely there will be a decrease in the use of polythene covers.

Let's celebrate an Eco-friendly Ganesh Chathurthi


Celebrating festivals is important. But celebrating festivals without doing any harm to the environment is more important.


Harmful

Even though our rivers are dry, we are polluting the remaining water bodies by immersing statue of Vinayakar. It is harmful. We should not pollute the environment which God created so beautifully.


Harmful chemicals


Usually, the Ganesha idols and statues are made of clay, which is easily soluble in water. But now, chemicals like plaster of paris, paints are used in making these idols, which is insoluble in water and pollutes the water bodies when immersed. The celebrations can be made eco-friendly by using water-soluble substances for making idol.


Suicidal

In the name of invoking the Almighty, we are unknowingly making the lovely environment an unfit place to live. Our acts are suicidal. We can not afford to pollute our water bodies by immersing hundreds of idols in the water. We need a revolutionary idea to bail us out of this situation. Its' better to prepare and prevent, than to repair and repent.


Haunting

The pollution caused after idol immersion is a haunting matter. The advent of Eco Friendly Ganesh idols may help us to celebrate the festival in full glory. We all should ensure a pollution free celebration.


Pompous

The ultimate aim of all religions is to enlighten people. Pompous display of idols and slogan shouting are part of demonstrative religious practice these days. However, these sentiments can still be tolerated provided the processions are noise, air and water pollution free, trouble free and also eco friendly. Till people understand the real spirit of religion which is inward journey or introspection, there is bound to be a lot of trial and error.


Emotional control

The Vinayaka Chathurti celebrations should not be considered a kind of merry

pastime which makes a dent in other religious beliefs. Mass celebrations should be kept under control emotionally.

Hazardous

Vinayaka Chathurti is one of the traditional religious rituals celebrated in Tamil Nadu in a grand manner. In earlier days, the Vinayaka idols were made of clay and easily dissolved in water. But now various chemicals are used in making them which are hazardous for the environment. People involved in making the Vinayaka idols must preserve nature and should make eco-friendly statues.

Respectfully

Each religious celebration has its own importance, if it is performed with respect and divinity. Vinayaka Chathurti can be celebrated without any feeling of disparity or discrimination without harming and hurting anyone and most importantly safeguarding the environment.


Repurcusions

It is our responsibility to keep our environment clean. During Vinayaka Chathurthi celebrations, we should take care not to pollute the water bodies. Hydrological ecosystem gets badly affected because these days lot of artificial colours and chemicals are being used in idol making. Immersing such harmful idols in rivers will have serious repurcussion later.


No interference

Motive of any festival is to spread a sense of happiness. We should enjoy festivals whole heartedly without interfering with the aquatic ecosystem. Though many rules and restrictions are there, there are flagrant violations too spoiling the environment.


Safe play

Celebrations are joyous occasions but this should be celebrated without

causing harm to the environment. Our environment is already polluted in many ways. Why should we cause further damage to it by immersing idols in lakes and rivers. Without this ritual too, the festival can be celebrated without losing its charm.


Natural dyes

Traditionally idols were made with clay, sandal, etc. But now to make idols more attractive, chemicals are used which are detrimental for the nature. Instead of chemicals, we can use fruits and vegetable mixture for painting the idols and making them eco-friendly.


Peaceful

"Our goal must be not peace in our time but peace for all time". Celebrating functions gives us peace of mind. But care should be taken that this does not spoil our environment. The statues of lord Vinayaga can be made with non-plastic items which dissolve easily in water and prevent pollution. We should all vow to celebrate vinayagar chaturthi in an eco friendly manner.


Awareness


Celebration is meant for happiness. But nowadays it affects the ecosystem. Ganesa idols painted with poisonous chemicals are immersed in rivers, lakes or seas. Rather, they should be disposed in a safe manner in order to avoid water pollution. People should be aware of eco friendly celebrations.


Keep city clean

Dissolving Vinayaka statues, that are made of plaster of paris and other chemical colouring agents in seas, rivers and other water bodies change the chemical composition of water. People should beware of those sellers and should buy only the eco-friendly statues that are made of clay. Throwing plantain leaves and waste food materials after pooja into the dustbin will make the city clean.


Break from monotony

Festivals and celebrations are a relief for the people from routine life. Vinayakar chathurthi is one such occasion. Making a huge colourful vinayakar statue with chemicals and dissolving them in the water surely pollutes. People should refrain from such environment-unfriendly acts.


Sacrifice

The Ganesha idols are made these in uncouth sizes and shapes are made out of papier mache and plaster of Paris. The number of Pillayars for public display and processions are increasing in number with each passing year. Immersing the idols in water pollutes the environment. We are sacrificing the serene atmosphere of religiosity.

Small and silent

Though it is one of the famous traditional festivals of the country, Vinayaka idols should be made small and taken through the streets silently, without disturbing the public. We should make our offerings to God with a pure heart and not by polluting the atmosphere.


Be traditional

Keeping the environment safe and clean is equivalent to offering prayers to the God. While celebrating Vinayakar Chathurti we should follow traditional methods like making

the idol with clay, worshipping with grass, making and offering sweets and sundal. Taking a procession of Vinayakar idols is not an ideal way of celebration. It affects public life.

Hey, Check out some of the wind turbines i made

TYPE 1


TYPE 2



TYPE 3


These are all wind turbines but they differ in their characteristics.

Type 1 is unique wind turbine which rotates the same way irrespective of whether wind is blowing forward or backward. For example if we assume that wind turbine revolves clockwise when wind blows from east to west, it would continue to do the same even when wind blows from west to east unlike type 2 and type 3 wind turbines. This is attributed to the aero-dynamic shape of the wings.


Difference between the type 2 and type 3 lies in the number of wings they have. More number of wings generate more torque i.e they provide more energy to the motor shaft to which they will ultimately be connected to, but the speed of rotation of wind turbine will be less

AVOID POLYTHENE CAMPAIGN

If we can make people recognize that protecting the environment is “Everyone’s Duty”, it will be a great leap in our efforts to save our environment.

With this in mind, I started my efforts to bring together and evolve ways in which we can lead a more environment friendly life and this campaign is an out put of my constant desire to do my part in keeping people aware and conscious about the deteriorating state of our environment.

Initially my idea was to bring paper covers into use in place of polythene covers. But it would be a costly affair. Even then it will be possible to use them in certain cases if we can get sponsorship. Later the idea of Paper C.D covers evolved.

Paper C.D Covers:

500 Paper C.D covers were prepared by me and they were distributed at free of cost in Stationary shops and in Internet cafes.

I made all the covers in my home and the print was done using stamps. I got 4 stamps prepared and i used two colors black and green to print the text. It took around two weeks to make the covers. My mother and brother have helped me a lot in doing this.

Prime motto behind this activity is to make people conscious about the fragile state of our environment. This is conveyed by the Phrase

SAVE THE ENVIRONMENT

SAVE THE PLANET

And the C.D covers are like a medium, which symbolically states you to “AVOID POLYTHENE WHEREVER POSSIBLE”. ‘Wherever possible’ keeps the statement open i.e. not restricting it to just the C.D Covers. I want to convey to the public to avoid polythene wherever they find a convenient/economically feasible option. Ex: Carrying a cloth bag when we go to shopping/vegetable market/ supermarket.

Avoiding Polythene itself Doesn’t do much good as its only a small drop in an ocean of troubles the environment is facing today and there are many issues that need to be addressed.

Here is one of the 500 covers that i distributed

IF WE CAN DO IT !!!

As you all people Know, India is a large country both in terms of its area and population. This fact itself says

a) how much pollution was/is being generated from our country (India is the 4th largest contributor of green house gases). and
b) how much contribution we can make to reduce the extent of pollution and thus Protect our Environment.

The major sources of pollution are :

A) Industries/ organizations
B) Transport Vehicles
C) Household pollution

Now, lets ask ourself 'what can we, as individuals do to deal with pollution.

Most of us are not so closely associated with industries. So, let's concentrate on Vehicles and Household pollution.

Coming to the transport vehicles, preliminary thing is that we need to realize the importance of public transport vehicles in reducing the amount of greenhouse gases emitted. Instead of going to your office alone in a car or on a bike, prefer to go by a bus. Next, think of using Electric Bikes & cars so that we can reduce our green house emissions. Even in the generation of electricity there is an element of pollution, but it is to an extent less compared to the use of fossil fuels. Employing Solar Energy, Wind Energy and Wave Energy will eliminate the pollution from electricity generation.


Domestic/ Household emissions are no less to emissions from the vehicles and industries. Green house gases do come out from our houses, ex: our gas stoves. Now you may ask , can we avoid Gas Stoves from our Homes. My answer is yes. But, i have a point to make clear to you. We cannot avoid it completely. We can avoid gas stoves in situations like cooking rice etc.
We can use CFL Bulbs instead of the tube lights/ Incandescent bulbs as the CFL bulbs are energy efficient i.e consume less electricity. It obviously means that less electricity needs to be produced and thus less amount of green house gases will be released during its production.
Some problems come to the surface in the Metropolitans. They include the above, and in addition other problems like Sewage Treatment, Solid waste management. We can treat our sewage right in our homes, We can Treat Some of our Solid waste as well. If we can do this, it will be a great job. These are just a few situations and we can bring a lot of Change if we all are committed to the cause of protecting the Environment.

Once we all can bring a change, even the industries / organizations will come forward to work for the cause of 'Protecting the Environment'.

So, Lets Say Together ,"We Indians will do our part to Protect the Environment".

BUILDINGS WITH INTEGRATED WIND TURBINES



PROJECT "WEB"



WIND ENERGY FOR THE BUILT ENVIRONMENT (PROJECT WEB)

Project WEB sought to demonstrate that the sensitive use of wind turbines in urban areas should be recognised by policy-makers as a realistic response to the global environmental challenges we face.

Many countries have vast largely untapped renewable wind resources. Yet, while 75% of the EU (European Union) population lives in urban areas and our buildings account for over 40% of overall energy demand, there are virtually no wind turbines in our towns and cities where the majority of electricity is consumed.

Key objectives were to address barriers to use (e.g. reduced wind speeds in urban areas, the size of turbines relative to buildings, noise problems, safety fears, planning restrictions) by developing innovative technological solutions and producing design guidance for the integration of wind turbines in, on and around buildings.
WEB considered 3 generic techniques for integration of wind turbines:

  • sensitively siting or landscaping stand-alone machines in urban environments, which can supply surrounding buildings;
  • retro-fitting turbines onto existing buildings;
  • full integration, such that the turbines drive the architectural form of a new building.

Techniques for full integration were successfully demonstrated by the field-testing of a 2-storey prototype building or wind concentrator with an integrated HAWT and VAWT during the project. Designed by the team and fabricated in the Netherlands, the FSM was shipped to the UK for erection and field-testing.

Suggested acronyms for describing the technology developed are ‘Urban Wind Energy Conversion Systems’ (UWECS) and ‘Building Augmented Wind Turbines’ (BAWTS).

Draft guidance for UWECS developments has also been produced. The guidelines cover the conceptual design process and include methodologies for predicting energy yield, and categorising and assessing environmental impacts and economic costs. There will be both external and internal environmental impacts for UWECS.

Source : http://www.bdsp.com/web/

MARS

Because the wind blows in different directions, because there isn't a constant air flow to get through and because not all regions get it, traditional turbines are no longer very efficient now that Mageen Power invented the airborne wind turbines. Apparently "at a thousand feet, there is steady wind anywhere in the world" said Mac Brown COO for Mageen.The company got a $5 million funding and managed to develop a lighter-than-air wind turbine that is filled with helium and has a 100-foot-wide Mageen Air Rotor System (MARS) that spins around a horizontal axis and produces 10kilowatts of energy. The whole turbine is wired to the ground with a copper cable and send energy down to be used (it can light up a small village) or can be stored in batteries.

There is a small concern about birds that would die flying inside. Mac Brown assured that being so big, bigger than a house, a bird would see it and a bat would sense it.Mageen Power got the paten for their MARS turbine in October and I can tell you I wish they'd start producing on a larger scale if there aren't any airplanes/helicopters problems related, because it's a very important source of energy involving minimum levels of pollution.

Source: NyTimes

MAGNETIC LEVIATION WIND TURBINE

It's a vision of a magnetically levitated wind turbine that can generate one gigawatt of power (enough to power 750,000 homes). This is the device proposed by a new Arizona-based company, MagLev Wind Turbine Technologies. The company claims that it can deliver clean power for less than one cent per kilowatt hour using this wind turbine.


Magnetic levitation is a very efficient method of capturing wind energy. The blades of the turbine are suspended on a cushion of air, and the energy is directed to linear generators with minimal fiction losses. But the big advantage with maglev is that it reduces maintenance costs, and increases the lifespan of the generator.

The company also points out that building a single huge turbine like this reduces construction and maintenance costs, and it requires less land space than hundreds of conventional turbines. The company is headed by Ed Mazur, a researcher of variable renewable energy sources since 1981 and inventor of the magnetic levitation wind turbine.

There has been speculation that turbines like these would use "full-permanent" magnets, meaning there are no electromagnets, only cleverly placed permanent ones (probably Halbach arrays).

China already has Maglev wind turbines in operation, see: The World's First "Magnetic Levitation" Wind Turbines Unveiled in China.

This article by WorldChanging goes into the technical details of using maglev in wind turbines.

Web site: MagLev Wind Turbine Technologies

LOOP WING WIND TURBINE

The above is the image of a wind turbine from the LoopWing company in Japan. This product is intended to be marketed for house owners who are interested in saving the planet and some money for them as well. this model e1500 is said to achieve 43% power performance at wind speeds of 8m/h.

INNOVATION



The above image shows a Highway Wind turbine. These would harness the wind generated by passing cars/trucks to create energy.

HAWT's & VAWT's

Horizontal Axis Wind Turbines & Vertical Axis Wind Turbines are the two types of Wind turbines.


Horizontal Axis Wind Turbines (HAWT) :

Horizontal Axis Wind Turbines are built with a propeller-type rotor on a horizontal axis (i.e. a horizontal main shaft).
HAWT's are the most common types of wind turbines you can see. most of the commercially installed wind generators are of this type.










Vertical Axis Wind Turbines (VAWT) :

The only vertical axis turbine which has ever been manufactured commercially at any volume is the Darrieus machine, named after the French engineer Georges Darrieus who patented the design in 1931. The Darrieus machine is characterised by its C-shaped rotor blades which make it look a bit like an eggbeater (you can see it in the image on the right). It is normally built with two or three blades.



THE LEADER IN WIND POWER


Wind Power -For Our Future - Funny blooper videos are here

WIND GENERATORS



Wind generators harness the wind energy to produce electricity.


The two essential components of a wind generator are:
1)wind turbine and
2)generator.

Ofcourse, there is another component. it is the pole on which the entire apparatus is mounted.

The wind turbine converts the energy of the wind into rotational energy. The rotational energy is used by the generator to produce electricity

Inside the body of a generator, there is a coil of wire and a magnet. When a coil of wire is moved inside a magnetic field, it produces an electric current in the wire - the same principle as a dynamo on a bicycle, but the wind
provides the movement, not your legs.

Wind generators come in many sizes and shapes, from small units found on caravans and boats to enormous machines that can power a whole village. Wind farms have many generators which produce a large amount of power. Some people object to wind generators on the grounds that they can be noisy and may be thought to spoil a beautiful view. Recently, wind farm planners and engineers have improved the noise problem considerably. Many people living near wind farms think that they enhance the view.

Perhaps the ultimate solution is to put wind generators offshore, where winds are strong and there are no neighbours.

Benefits

Wind generators are the main viable alternative to fossil fuels and nuclear power : as such wind power has the potential to replace currently existing generating technologies which cause a wide range of environmental problems. Wind power does not contribute in use to climate change or acid rain, and does not create a hazardous waste storage problem.

Wind generators have a good energy ratio: they generate many times the energy needed to make them(this is not the case with solar Panels). Also, it is easy to decommission wind power installations (unlike the nuclear power plants); most of the materials are easily recyclable using existing technologies.

Greater use of wind power means less dependency on remote fuel sources, with the problems of transport and military involvement that brings.

Wind power is suitable for small installations, unlike many other generation technologies which are only viable on a large scale.

Safety and reliability are good - a properly installed wind generator will operate without problems for 20 years or more, and there is no record of any member of the public ever being harmed by an operational wind turbine.

What can we do?

It’s a good idea to combine wind with solar, to take advantage of all weather conditions (plus the wind blows at night) to provide all, or contribute to, your energy needs.


If you want to provide all your needs, the first task is to reduce energy use and become more energy efficient, otherwise it will be quite expensive. Wind generators are ideal for boats and caravans though, where less electricity is needed, and also for remote, off-the-grid homes, in conjunction with a diesel generator - especially if heating is solid fuel, and cooking is with bottled gas.
Check the wind speeds at your location, or monitor them yourself - you can get monitoring equipment from wind and sun, then look at graphs provided by manufacturers for their turbines to see what power (in Watts) you will get for your average windspeed. Divide by 1000 to get kW, and multiply by the number of hours in a year (8760) to find the kWh generated per year (a kWh is a unit of electricity and can be found on your electricity bill).
Talk to your local planners (for a small turbine, this shouldn’t be a problem), and choose a site away from trees and buildings (rural areas are much better sites for wind generators).
Decide whether you will use a battery bank, or be grid connected (in effect using the grid as a store instead of batteries). There are environmental problems in the manufacture and disposal of batteries, but electricity companies often pay a lot less for energy received than supplied (although this may be changing). There is a third way, called grid interface. Batteries are used but the grid kicks in via a transfer switch if the batteries get low. You can slowly add more wind and solar to reduce the need for grid power.
You can buy 12-volt domestic appliances, in which case you just need batteries and a regulator, or you can use normal 240v appliances, but you’ll need an inverter too. You can self-install or you can employ a professional.
In some countries (for ex : U.K) a government grant is available for wind generator installations.

WIND ENERGY AN INDIRECT FORM OF SOLAR ENERGY???


Wind Energy is an indirect form of Solar Energy
. About 1% of the total solar radiation that reaches earth is converted into energy of wind. Wind results from differential heating of the earth and its atmosphere by sun. As the sun heats different parts of the earth at different rates, air circulates from cold to warm areas producing winds. Wind energy has been used for thousands of years to propel sailing ships and for pumping water and grinding grain.

The application of wind energy has several advantages like:

  • low gestation period
  • no raw-material cost
  • non-polluting etc.

SOLAR THERMAL POWER

Solar energy can be produced a great amount of green electricity. As we all know solar panels are used for this purpose. But they are expensive. To answer these problems i have two solutions :

  • We an produce electricity from the sun even with out using solar panels. we can use reflectors to reflect all the sun light onto a certain area which receives the heat to generate steam. the steam, as usually is used to rotate the turbines to generate electricity.

  • The other way is to concentrate the solar energy onto solar panels. The difference between this method and using solar panels alone is that less number of solar panels (and thus less cost) are needed to harness the same amount of energy.
As i mentioned in the earlier post, the advent of the darkest substances can help a lot in increasing our efficiency in using the energy of the sun.

THE DARKEST SUBSTANCE ON EARTH

U.S. researchers have made the darkest material on Earth, a substance so black it absorbs more than 99.9 percent of light.

Made from tiny tubes of carbon standing on end, this material is almost 30 times darker than a carbon substance used by the U.S. National Institute of Standards and Technology as the current benchmark of blackness.
And the material is close to the long-sought ideal black, which could absorb all colours of light and reflect none.
"All the light that goes in is basically absorbed," Pulickel Ajayan, who led the research team at Rice University in Houston, said in a telephone interview. "It is almost pushing the limit of how much light can be absorbed into one material."
The substance has a total reflective index of 0.045 percent -- which is more than three times darker than the nickel-phosphorous alloy that now holds the record as the world's darkest material.
Basic black paint, by comparison, has a reflective index of 5 percent to 10 percent.
The researchers are seeking a world's darkest material designation by Guinness World Records. But their work will likely yield more than just bragging rights.
Ajayan said the material could be used in solar energy conversion.

i think this is really a good news for the future of solar power

SOLAR BAGS ???


Carrying Power - Solar Power On The Go - Click here for the funniest movie of the week

SOLAR CARPORTS ???


Solar Power - Solar Panels - Solar Powered Carport - For more of the funniest videos, click here

HOW ARE SOLAR PANELS MADE ?


How It's Made - Solar Panels - The best video clips are right here

SOLAR PANELS - FUTURE


Solar Panels Future, Energy Generation and Global Warming - The best home videos are here

SOLAR ELECTRICITY


What is Solar Electricity?

It is the generation of electricity from the power of the sun, via photovoltaic (pv) cells. It is different from solar water heating, where water passes through panels to be heated directly, and no electricity is generated.
Photovoltaic cells are made from silicon; when particles of sunlight (photons) fall on the cells, they dislodge the outer electrons of their atoms, and push them along to the next atom; a chain of moving electrons is produced, and if a wire is attached to the panels, these electrons can be
pushed down it to supply a useable electric current. This current is measured in amps, and to give some idea of the scale involved, one amp of current involves the movement of 6 million million million electrons per second.
The electricity produced this way (and also from batteries) flows in one direction only, and so is called direct current, whereas electricity from the grids is alternating current, as the flow of electrons changes direction 50 times per second. Direct current can be stored in batteries to power 12 volt appliances. However, these are more expensive and less readily available than ordinary domestic 240 volt appliances, so batteries and an inverter can be used to convert the 12 volt direct current to 240 volt alternating current, or the panels can be connected to the grid, with a meter to see how much electricity is put into the grid and how much taken from it. A grid-support system is one which charges batteries, and re-directs any surplus into the grid if the batteries are full.

What are the benefits?

As a renewable source of energy, the main environmental benefits of pv is that it doesn't cause the problems that other types of electricity generation do.
Burning fossil fuels in conventional power stations releases nitric oxides, nitrogen dioxide and sulphur dioxide, causing acid rain which damages forests, wildlife and human health; it also releases carbon monoxide, nitrous oxides, lead, particulates and hydrocarbons, which cause damage to plants, ecosystems, and human health, especially respiratory problems. Also, burning fossil fuels releases 5 billion tonnes of CO2 into the atmosphere each year. CO2 is the most important of the ‘greenhouse gases’ responsible for global warming.

With pv there are no emissions, no environmentally-damaging extraction and transport of coal and oil to feed power stations, and no radioactive waste, or the potential leaks and disasters associated with nuclear power stations.

Disadvantages :

  • Pvs take around 5 years to generate the same amount of electricity as is used in their manufacture - see this research paper (pdf) from Pennsylvania State University.
  • Large-scale use of lead-acid batteries would cause environmental problems in their manufacture and disposal, so connection to the grid would be better unless in a remote location.


What can we do?

A single panel can be used with a battery to power lights or animal fencing in a remote location, or you can attempt to supply all or most of your electricity with a large system.
The first thing to do is find out how much electricity (in kilowatt-hours, kWh) you use in a year (check your bills), and think about ways to reduce your usage:

  • switch lights off when you leave the room.
  • don’t leave appliances on standby.
  • use a laptop (c. 18 watts) instead of a desktop (c. 180 watts).
  • use Savaplugs and low-energy light bulbs and appliances.
  • don’t overfill kettles.
  • think about solar hot water and a wood-burning stove, and whether you need so much electrical gear at all.


SAVAplugs use electronic technology to regulate the electricity to match the actual demand required by the motor. SAVAplugs simply replace the original manufactured mains electrical plug




A typical family in UK will use about 3000-4000kWh per year, but if you are single, have no children and / or reduce your electricity use, we can work with a figure of 2000kWh / year. Taking the annual amount of sunshine into consideration, this will require a 2.4kW system, covering 20m², and costing around £16,000 installed. There is now a £2500 government grant in the UK for professionally-installed, grid-connected systems (see below), which will reduce this to £13,500. With electricity at around 11p per kWh this will save £220 per year, giving a payback time of 60 years and saving about 2 tonnes of carbon. The payback time is way too long at the moment, but will come down as fossil fuel prices rise, and if the UK government start supporting photovoltaics as much as the German govt. It could be cost-effective for remote locations where the cost of grid connection is prohibitive.
The cost can’t be reduced by self-build (like solar hot water), because the manufacturing process is too high-tech, but you could self-install if you have the know-how. Of course you could use pv in conjunction with a wind turbine to take advantage of all weather conditions.

Other factors to consider are: is your roof south-facing? is it big enough? (if not, panels could be located on a frame in the garden or on a flat roof) is it shaded? (panels can be damaged if parts of them are shaded) if you are using batteries they need to be deep-cycle (able to be continuously drained and re-charged) with a charge regulator to prevent overcharging.

INDIA & ENERGY SECURITY

A nation can be prosperous & stable only when it is 'energy secured'. If we think about india in the current scenario, we should say that india is not energy secured. I have strong reasons to support what I feel

  • India is at present meeting a major proportion of its crude oil needs through imports.
  • Major proportion of our power needs are met through the thermal energy from coal.










The Oil Situation :

We have the oil reserves & definitely there isn’t a need to import as much as we are at present. The only problem is that we are not making sincere efforts to find the reserves and to make a produce from them.

Only 20 % of the country is surveyed in search for the crude oil/natural gas reserves. In that 20 %, the reserves found are not being exploited. It was in 1960’s when the presence of the reserves was indicated in Krishna – Godavari basin. But even by now (2008) production has not started. This is the situation in our country. “Policy makers who lack a proper commitment & vision”, this the biggest problem india has been facing. The trend has never changed and is becoming even worse with the progress of time. Lets put behind the politicians.

Ofcourse we cant completely rely on Oil, gas resources in our country even, as our needs have increased & will increase further drastically. We have to search for other alternative sources like biodiesel powered, electricity powered, water powered vehicles to reduce our dependence on imports from other countries.

The Electricity situation :

We all know about the nuclear deal. Our government is rushing for this deal to come into existance. I feel that there isn't a need for the rush to give our nation the 'nuclear energy'.

There are other sources such as :

  • wind energy
  • solar energy
  • wave energy

The above three mentioned are renewable and have great potential. Their potential combined is greater than the potential needed to be met world wide.

It was in 1940s/1950s when nuclear energy was first used to produce electricity. At present only 6% of the worlds energy needs are being met by nuclear plants. The disadvantages associated with nuclear power are :

  • The construction of nuclear reactors takes a long time (from now) within which a great leap can be achieved in the renewable energy technologies (solar,wind,wave energies).
  • When accidents happen they will have a huge impact on the lives of the present & future generations as well.
  • The waste coming out has to safely discarded. The waste continues to emit radiation for thousands of years. We should remember that we have no rights to poison our future generations.
  • They are not economical as well. They require heavy subsidies from the government.
Nuclear energy contributes less than 3% to the total electricity generated in our country.

India at present is having the capacity of 140 giga watts. It has to increase to 1000 giga watts in order to meet the increasing needs of the nation. So we need to make a step in making developing & making use of sustainable energy forms. Only then can we become energy secured & develop into a prosperous nation.




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Carry a Cloth bag/a Basket when you go out to a Market