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Details of Hydrogen Vehicle

A hydrogen vehicle is a vehicle that uses hydrogen as its on-board fuel for motive power. The term may refer to a personal transportation vehicle, such as an automobile, or any other vehicle that uses hydrogen in a similar fashion, such as an aircraft. The power plants of such vehicles convert the chemical energy of hydrogen to mechanical energy (torque) in one of two methods: combustion, or electrochemical conversion in a fuel-cell:
* In combustion, the hydrogen is burned in engines in fundamentally the same method as traditional gasoline (petrol) cars.
* In fuel-cell conversion, the hydrogen is reacted with oxygen to produce water and electricity, the latter of which is used to power an electric traction motor.

Vehicles
Buses, trains, bicycles, cargo bikes, golf carts, motorcycles, wheelchairs, ships, airplanes, submarines, high-speed cars ,and rockets already can run on hydrogen, in various forms and sometimes at great expense. NASA uses hydrogen to launch Space Shuttles into space. There is even a working toy model car that runs on solar power, using a reversible fuel cell to store energy in the form of hydrogen and oxygen gas. It can then convert the fuel back into water to release the solar energy.
The current land speed record for a hydrogen powered vehicle is 333.38 km/h (207.2 mph) set by a prototype Ford Fusion Hydrogen 999 Fuel Cell Race Car at Bonneville Salt Flats in Wendover, Utah on August 2007.

Automobiles
Many companies are currently researching the feasibility of building hydrogen cars and most of the automobile manufacturers have begun developing hydrogen cars,Most of these vehicles are currently only available in demonstration models or in a lease construction in limited numbers and are not yet ready for general public use. The recorded number of hydrogen-powered public vehicles in the United States was 200 as of April 2007, mostly in California, Funding has come from both private and government sources.

Buses
Main article: fuel cell bus
Fuel cell buses (as opposed to hydrogen fueled buses) are being trialed by several manufacturers in different locations. The Fuel Cell Bus Club is a global fuel cell bus testing collaboration.
Hydrogen was first stored in roof mounted tanks, although models are now incorporating inboard tanks. Some double deck models uses between floor tanks.

Bicycles
Pearl Hydrogen Power Sources of Shanghai, China, unveiled a hydrogen bicycle at the 9th China International Exhibition on Gas Technology, Equipment and Applications in 2007.

Motorcycles
ENV is developing electric motorcycles powered by a hydrogen fuel cell, including the Crosscage and Biplane.

Airplanes
Companies such as Boeing and Smartfish are pursuing hydrogen as fuel for airplanes. Unmanned hydrogen planes have been tested, and in February 2008 Boeing tested a manned flight of a small aircraft powered by a hydrogen fuel cell. The Times reported that "Boeing said that hydrogen fuel cells were unlikely to power the engines of large passenger jets but could be used as backup or auxiliary power units onboard."

Hydrogen internal combustion
Hydrogen internal combustion engine cars are different from hydrogen fuel cell cars. The hydrogen internal combustion car is a slightly modified version of the traditional gasoline internal combustion engine car. These hydrogen engines burn fuel in the same manner that gasoline engines do.

Francois Isaac de Rivaz designed in 1807 the first internal combustion engine on hydrogen Paul Dieges patented In 1970 a modification to internal combustion engines which allowed a gasoline powered engine to run on Hydrogen US patent 3844262.

Mazda has developed Wankel engines that burn hydrogen. However the major car companies such as DaimlerChrysler and General Motors are investing in the more efficient hydrogen fuel cells instead.

Hydrogen fuel cell
While fuel cells themselves are potentially highly energy efficient, and working prototypes were made by Roger E. Billings in the 1960s, at least four technical obstacles and other political considerations exist regarding the development and use of a fuel cell-powered hydrogen car.

Fuel cell cost
Currently, hydrogen fuel cells are costly to produce and are fragile. Engineers are studying how to produce inexpensive fuel cells that are robust enough to survive the bumps and vibrations that all automobiles experience. Also, many designs require rare substances such as platinum as a catalyst in order to work properly. Such a catalyst can also become contaminated by impurities in the hydrogen supply. In the past few years, however, a nickel-tin catalyst has been under development which may lower the cost of cells.

Fuel cells are generally priced in USD/kW, and data is scarce regarding costs. Ballard Power Systems is virtually alone in publishing such data. Their 2005 figure was $73 USD/kW (based on high volume manufacturing estimates), which they said was on track to achieve the U.S. DoE's 2010 goal of $30 USD/kW. This would achieve closer parity with internal combustion engines for automotive applications, allowing a 100 kW fuel cell to be produced for $3000. 100 kW is about 134 hp.

Freezing conditions
Freezing conditions are a major consideration because fuel cells produce water and utilize moist air with varying water content. Most fuel cell designs are fragile and cannot survive in such environments at startup but since heat is a byproduct of the fuel cell process, the major concern is startup capability. Ballard announced that it has already hit the U.S. DoE's 2010 target for cold weather starting which was 50% power achieved in 30 seconds at -20 °C. Although this is a good step, there still has to be many more improvements in that area for fuel cells to be strong enough to hold up to hard weather.

Service life
Although service life is coupled to cost, fuel cells have to be compared to existing machines with a service life in excess of 5000 hours for stationary and light-duty. Marine PEM fuel cells reached the target in 2004 Research is going on especially for heavy duty like in the bus trails which are targeted up to a service life of 30,000 hours.

Hydrogen production
The molecular hydrogen needed as an on-board fuel for hydrogen vehicles can be obtained through many thermochemical methods utilizing natural gas, coal (by a process known as coal gasification), liquefied petroleum gas, biomass (biomass gasification), by a process called thermolysis, or as a microbial waste product called biohydrogen or Biological hydrogen production. Hydrogen can also be produced from water by electrolysis. Current technologies for manufacturing hydrogen use energy in various forms, totalling between 25 and 50 percent of the higher heating value of the hydrogen fuel, to produce, compress or liquefy, and transmit the hydrogen by pipeline or truck.Electrolysis, currently the most inefficient method of producing hydrogen, uses 65 percent to 112 percent of the higher heating value on a well-to-tank basis.Environmental consequences of the production of hydrogen from fossil energy resources include the emission of greenhouse gases, a consequence that would also proceed from the on-board reforming of methanol into hydrogen. Studies comparing the environmental consequences of hydrogen production and use in fuel cell vehicles to the refining of petroleum and combustion in conventional automobile engines find a net reduction of ozone and greenhouse gases in favor of hydrogen. Hydrogen production using renewable energy resources would not create such emissions or, in the case of biomass, would create near-zero net emissions assuming new biomass is grown in place of that converted to hydrogen. The scale of renewable energy use today is insufficient and would need to be greatly increased to meet demand for widespread use in transportation.However, in a few countries, hydrogen is being produced using renewable sources. For example, Iceland is using geothermal power to produce hydrogen, and Denmark is using wind.

In addition to the inherent losses of energy in the conversion of feed stock to produce hydrogen which makes hydrogen less advantageous as an energy carrier, there are economic and energy penalties associated with packaging, distribution, storage and transfer of hydrogen.

Hydrogen storage
Hydrogen has a very low volumetric energy density at ambient conditions, equal to about one-third that of methane. Even when the fuel is stored as a liquid in a cryogenic tank or in a pressurized tank, the volumetric energy density (megajoules per liter) is small relative to that of gasoline. Hydrogen has a three times higher energy density by weight compared to gasoline (143 MJ/kg versus 46.9 MJ/kg). Because of the energy required to compress or liquefy the hydrogen gas, the supply chain for hydrogen has lower well-to-wheel efficiency but a higher tank-to-wheel compared to gasoline IC's. Some research has been done into using special crystalline materials to store hydrogen at greater densities and at lower pressures.

Hydrogen infrastructure
The hydrogen infrastructure consists mainly of industrial hydrogen pipeline transport and hydrogen-equipped filling stations like those found on a hydrogen highway. Hydrogen stations which are not situated near a hydrogen pipeline get supply via hydrogen tanks, hydrogen tube trailers, liquid tankers or dedicated onsite production.

Hydrogen use would require the alteration of industry and transport on a scale never seen before in history. For example, according to GM, 70% of the U.S. population lives near a hydrogen-generating facility but has just about no access to hydrogen, despite its wide availability for commercial use. The distribution of hydrogen fuel for vehicles in the U.S. would require new hydrogen stations costing, by some estimates, 20 billion dollars.and 4.6 billion in the EU.Other estimates place the cost as high as half trillion U.S. dollars in the United States alone.

Hydrogen economy
Hydrogen does not come as a pre-existing source of energy like fossil fuels, but rather as a carrier, much like a battery. It can be made from both renewable and non-renewable energy sources. The common internal combustion engine, usually fueled with gasoline (petrol) or diesel liquids, can be converted to run on gaseous hydrogen. However, the more energy efficient use of hydrogen involves the use of fuel cells and electric motors. Hydrogen reacts with oxygen inside the fuel cells, which produces electricity to power the motors. A primary area of research is hydrogen storage, to try to increase the range of hydrogen vehicles, while reducing the weight, energy consumption, and complexity of the storage systems. Two primary methods of storage are metal hydrides and compression.

A potential advantage of hydrogen is that it could be produced and consumed continuously, using solar, water, wind and nuclear power for electrolysis. Currently, however, hydrogen vehicles utilizing hydrogen produce more pollution than vehicles consuming gasoline, diesel, or methane in a modern internal combustion engine, and far more than plug-in hybrid electric vehicles.This is because, although hydrogen fuel cells generate no CO2, production of the hydrogen creates additional emissions.While methods of hydrogen production that do not use fossil fuel would be more sustainable,currently such production is not economically feasible, and diversion of renewable energy (which represents only 2% of energy generated) to the production of hydrogen for transportation applications is inadvisable.
The production of hydrogen with electricity makes it an energy carrier, and not an energy source, so the energy the car uses would ultimately need to be provided by a conventional power plant or a home hydrogen station. A suggested benefit of large-scale deployment of hydrogen vehicles is that it could lead to decreased emissions of greenhouse gases and ozone precursors. Further, the conversion of fossil fuels would be moved from the vehicle, as in today's automobiles, to centralized power plants in which the byproducts of combustion or gasification may be better controlled than at the tailpipe. However, there are both technical and economic challenges to implementing wide-scale use of hydrogen vehicles, as well as less expensive alternatives. The timeframe in which challenges may be overcome is likely to be at least several decades, and hydrogen vehicles may never become broadly available. For mobile applications, hydrogen has been called "one of the least efficient, most expensive ways to reduce greenhouse gases".

Most of today's hydrogen is produced using fossil energy resources. While some advocate hydrogen produced from non-fossil resources, there could be public resistance or technological barriers to the implementation of such methods. For example, the United States Department of Energy currently supports research and development aimed at producing hydrogen utilizing heat from generation IV reactors. Such nuclear power plants could be configured to cogenerate hydrogen and electricity. Hydrogen produced in this fashion would still incur the costs associated with transportation and compression or liquefaction assuming direct (molecular) hydrogen is the on-board fuel. Recently, alternative methods of creating hydrogen directly from sunlight and water through a metallic catalyst have been announced. This may eventually provide an economical, direct conversion of solar energy into hydrogen a very clean solution for hydrogen production.

Some in Washington advocate schemes other than hydrogen vehicles to replace the petroleum-based internal combustion engine vehicles. Plug-in hybrids, for example, would augment today's hybrid gasoline-electric vehicles with greater battery capacity to enable increased use of the vehicle's electric traction motor and reduced reliance on the combustion engine. The batteries would be charged via the electric grid when the vehicle is parked. Electric power transmission is about 93 percent efficient and the infrastructure is already in place. Tackling the current drawbacks of electric cars or plug-in hybrid electric vehicles is believed by some to be easier than developing a whole new hydrogen infrastructure that mimics the obsolete model of oil distribution. A plug-in hybrid transportation system would face the same thermodynamic hurdles as would a system of hydrogen vehicles relying on electrolysis for its molecular hydrogen. The current electric grid, which is dominated by fossil energy resources in the United States, has a fuel-to-power efficiency of roughly 40 percent. Both the plug-in hybrids and the electrolytic hydrogen system would be subject to these comparative inefficiencies.

United States President George W. Bush was optimistic that these problems could be overcome with research. In his 2003 State of the Union address, he announced the U.S. government's hydrogen fuel initiative,which complements the President's existing FreedomCAR initiative for safe and cheap hydrogen fuel cell vehicles. Critics charge that focus on the use of the hydrogen car is a dangerous detour from more readily available solutions to reducing the use of fossil fuels in vehicles. K.G. Duleep speculates that "a strong case exists for continuing fuel-efficiency improvements from conventional technology at relatively low cost." Challenging perspectives to many such critics of hydrogen vehicles in particular and of a hydrogen economy in general were presented in the 2006 documentary, Who Killed the Electric Car?

President Bush's hydrogen car goals, in the opinion of some writers, are slipping away because "there are quicker, cleaner, safer and cheaper ways to reduce the tail-pipe emissions from cars and trucks that pollute the air and contribute to global warming." According to physicist and former U.S. Department of Energy official Joseph Romm, "A hydrogen car is one of the least efficient, most expensive ways to reduce greenhouse gases." Asked when hydrogen cars will be broadly available, Romm replied: "Not in our lifetime, and very possibly never." As an article published in the March/April 2007 issue of Technology Review argued,
In the context of the overall energy economy, a car like the BMW Hydrogen 7 would proba­bly produce far more carbon dioxide emissions than gasoline-powered cars available today. And changing this calculation would take multiple breakthroughs--which study after study has predicted will take decades, if they arrive at all. In fact, the Hydrogen 7 and its hydrogen-fuel-cell cousins are, in many ways, simply flashy distractions produced by automakers who should be taking stronger immediate action to reduce the greenhouse-gas emissions of their cars.

The Wall Street Journal reported that "Top executives from General Motors Corp. and Toyota Motor Corp. Tuesday expressed doubts about the viability of hydrogen fuel cells for mass-market production in the near term and suggested their companies are now betting that electric cars will prove to be a better way to reduce fuel consumption and cut tailpipe emissions on a large scale." In addition, Ballard Power Systems, a leading developer of hydrogen vehicle technology, pulled out of the Hydrogen vehicle business in late 2007. Research Capital analyst Jon Hykawy concluded that Ballard saw the industry going nowhere and said: "In my view, the hydrogen car was never alive. The problem was never could you build a fuel cell that would consume hydrogen, produce electricity, and fit in a car. The problem was always, can you make hydrogen fuel at a price point that makes any sense to anybody. And the answer to that to date has been no."

Alternatives
PHEVs
ICE-based hybrid cars can be plugged into the electric grid (Plug-in hybrid electric vehicles, or PHEVs) and achieve much higher overall gas mileage and lower emissions than other hybrids. A 2006 article in Scientific American argues that PHEVs, rather than hydrogen vehicles, will soon become standard in the automobile industry.

EVs
Electric cars, such as the General Motors EV1 are typically more efficient than fuel cell-powered vehicles on a well-to-wheel basis. As Technology Review noted in June 2008, "Electric cars—and plug-in hybrid cars—have an enormous advantage over hydrogen fuel-cell vehicles in utilizing low-carbon electricity. That is because of the inherent inefficiency of the entire hydrogen fueling process, from generating the hydrogen with that electricity to transporting this diffuse gas long distances, getting the hydrogen in the car, and then running it through a fuel cell—all for the purpose of converting the hydrogen back into electricity to drive the same exact electric motor you'll find in an electric car. For this reason, battery powered vehicles are gaining popularity, particularly with the introduction of new models like the Tesla Roadster.

Type: Glossary & Dictionary