Your Fuel Cell Car example essay topic

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Fuel cell technology 1 Running head: FUEL CELL TECHNOLOGY: TRANSPORTATION AND RESIDENTIAL / COMMERICAL APPLICATIONS Fuel Cell Technology: Transportation and residential / commercial applications Monique University 2 A fuel cell is an electrochemical energy conversion device. A fuel cell converts the chemicals hydrogen and oxygen into water, and in the process it produces electricity. With a fuel cell, chemicals constantly flow into the cell so it never goes dead as long as there is a flow of chemicals into the cell, the electricity flows out of the cell. Most fuel cells in use today use hydrogen and oxygen as the chemicals.

Fuel cell provides a DC (direct current voltage that can be used to power motors, lights or any number of electrical appliances. The fuel cell will compete with many other types of energy conversion devices, including the gas turbine in your city's power plant, the gasoline engine in your car and the battery in your laptop. Combustion engines like the turbine and the gasoline engine burn fuels and use the pressure created by the expansion of the gases to do mechanical work. Batteries converted chemical energy back into electrical energy when needed.

Fuel cells should do both tasks more efficiently. Fuel cells improve battered powered cars and gasoline powered cars more efficiently. Fuel-cell-powered electric cars are powered with pure hydrogen. It has the potential to be up to 80% 3 efficient, and with today's gas prices that would be wonderful. The efficiency of a gasoline-powered car is surprisingly low. All of the heat that comes out as exhaust or goes into the radiator is wasted energy.

The engine also uses a lot of energy turning the various pumps, fans and generators that keep it going. So the overall efficiency of an automotive gas engine is about 20%. That is, only about 20% of the thermal-energy content of the gasoline is converted into mechanical work. The efficiency of an electric car is 72% for the car, 40% for the power plant and 90% for charging the car. That gives an overall efficiency of 26%.

The overall efficiency varies considerably depending on what sort of power plant is used. If the electricity for the car is generated by a hydroelectric plant for instance, then it is basically free (we didn't burn any fuel to generate it), and the efficiency of the electric car is about 65%. 4 Efficiency is not the only consideration, however. People will not drive a car just because it is the most efficient if it makes them change their behavior. They are concerned about many other issues as well. Such as; is the car quick and easy to refuel, can it travel a good distance before refueling, is it as fast as the other cars on the road, and how much pollution does it produce?

Fuel-cell-powered cars will start to replace gas- and diesel-engine cars in about 2005. A fuel-cell car will be very similar to an electric car but with a fuel cell and reformer instead of batteries. Most likely, you will fill your fuel-cell car up with methanol, but some companies are working on gasoline reformers. Other companies hope to do away with the reformer completely by designing advanced storage devices for hydrogen.

Fuel cells also make sense for portable electronics like laptop computers, cellular phones or even hearing aids. In these applications, the fuel cell will provide much longer life than a battery would, and you should be able to" recharge' it quickly with a liquid or gaseous fuel. Fuel-cell-powered buses are already running in several cities. The bus was one of the first applications of the fuel cell because initially, fuel cells needed to be quite 5 large to produce enough power to drive a vehicle. In the first fuel-cell bus, about one-third of the vehicle was filled with fuel cells and fuel-cell equipment.

Now the power density has increased to the point that a bus can run on a much smaller fuel cell. This is a promising application that you may be able to order as soon as 2002. General Electric is going to offer a fuel-cell generator system made by Plug Power. This system will use a natural gas or propane reformer and produce up to seven kilowatts of power (which is enough for most houses).

A system like this produces electricity and significant amounts of heat, so it is possible that the system could heat your water and help to heat your house without using any additional energy. Some fuel-cell technologies have the potential to replace conventional combustion power plants. Large fuel cells will be able to generate electricity more efficiently than today's power plants. The fuel-cell technologies being developed for these power plants will generate electricity directly from hydrogen in the fuel cell, but will also use the heat and water produced in the cell to power steam turbines and generate even more electricity. There are already large portable fuel-cell systems available for providing backup power to hospitals and factories. There are several types of fuel cells.

The chart below shows the different types of fuel cells, their operating temperatures, their utility power, their applications, their costs, their size, and the electrical efficiency as pertaining to the device their associated with. You will also note in the chart that fuel cell technology is proficient in residential and commercial buildings, passenger vehicles (not all fuel cell technology will be used in vehicles), and other power applications. Table 1: Types of Fuel Cells Proton Exchange Membrane Fuel Cell (PEM) Alkaline Fuel Cell (AFC) Phosphoric Acid Fuel Cell (PAF C) Molten Carbonate Fuel Cell (MCF C) Solid Oxide Fuel Cell (SOFT) Electrolyte Ion Exchange membrane (solid polymer) Potassium Hydroxide (KOH) Aqueous Phosphoric Acid Molten Carbonates Solid Ceramic Catalyst Platinum Ruthenium Platinum / Palladium Platinum Nickel / Nickel-Oxide Not required Cell Operating Temperature (^0 C) 80-100 80-100 400 600-700 600-1,000 Electrical System Efficiency (%, LV) 35-50 50-60 40 45-65 50-70 Typical Size (kW) Residential: 1-10/Commercial: 75-250 25-100 200 250 multi-megawatt Residential: 3-10/Commercial: ~250 Cost per kW (US$) 4,250 Some Applications Commercial Buildings YES YES YES YES YES Cogeneration YES YES YES YES YES Residential YES YES YESUtility Power YES YES YES Distributed Power YES YES YES YES YESUtility Re powering YES YES YES Passenger Vehicles YES YES Passenger Vehicle Auxiliary Power Units YES YES Heavy Duty Vehicles YES YES YES YES Portable Power YES There are many organizations involved with fuel cell codes and standards. Some of them are vehicle manufacturers such as; Renault, Honda, Ford, Toyota, and General Motors just to name a few.

There are also fuel cell manufacturers who are involved with the codes and standards. They are; International Fuel Cells, Millennium Cell, McDermott Technology, and Gore just to name a few. Suppliers who are involved with the standards and codes are Johnson Control, Zeon Chemicals, and Unifrax among others. Collaborative Organizations include ISO / TC 22/SC 21, Japan Electric Vehicle Association (JAVA), and US Fuel Cell Council just to name a few.

There are four main reasons why fuel cells are highly desirable for the U.S. to develop them. The first would for greater energy security and independence, mechanical breakdowns, storms, growing demand for energy generation, and political conflict throughout the world, and fuel cell are more particularly for systems requiring 24/7 operation. Another reason is the distribution of energy and the concept of having smaller systems instead of have on huge system. One more reason would be the opportunities for economic developments, because each new fuel cell company would create jobs directly from the manufacture, design, installation, servicing, and marketing of fuel cells. Most importantly would be unlimited applications and uses. Although fuel cell technology as been around since the mid 1800's.

Sir William Grove other wise known as the "Father of Fuel Cell", discovered that it may be possible to generate energy electricity by reversing the electrolysis of water. It wasn't until 1889 that Charles Langer and Ludwig Mond coined the first term "fuel cell" when they engineered the first practical fuel cell using air and coal gas. Francis Bacon developed what was the first successful fuel cell device in 1932. Harry Karl Ih rig presented his 20-horsepower fuel cell powered tractor in 1959.

NASA got involved in the late 1950's when they built a compact electricity generator for use on space missions. They later funded hundreds of research involving fuel cell technology. That research improved the space program after supply electricity to several space missions. There are a lot of new companies and old companies involved in fuel cell technology. The market is booming with new and old investors of fuel cell companies.

Companies from all over the world as well as investors are getting ready for the future in fuel cell technology. Several organizations now have conferences every year to discuss the future of fuel cell technology. In 2005, the second annual conference designed for organizations throughout North America interested in learning more about applying fuel cell technology was convened. The two-day conference provides an interactive forum for OEMS, designers, engineers, and integrators to discuss the latest capabilities in fuel cell, components, material, and system integration. There is no doubt about it, within the next decade, fuel cells will be providing energy for cars, and trucks, producing electricity for utilities, and heating and cooling homes and businesses. They may even replace the expensive batteries in personal computers with power sources that can run for almost a year on a teaspoonful of alcohol.

The fuel cell will transform the energy industry. Some companies have already become leaders in fuel cell development. Major automakers as discussed before are planning to integrate the fuel cell into their long-range strategies. Some market analysts predict that fuel cells will become a billion dollar market in the next decade.

In the past fuel cell technology prices were very expensive. Now fuel cell prices are beginning to come down for a number of reasons and by a variety of measures. Performance is increasing along with reliability and durability across the board. Innovation is presenting new options to achieve real products for real markets. There have been and continue to be early production runs that cover several generations of products. Hundreds of residential systems are being deployed in Europe and Japan.

The small fleet of fuel cell vehicles in the U.S., Europe, and Japan continue to grow. Many of the innovations that are being achieved are because of the growing sophistication of simulation software that allows engineers and scientists to work on problems and to evaluate new concepts, configurations and material before new material is purchased. This reduces development costs significantly.