The Fuel Cell of the future
Air
Hydrogen
Waste heat + Water vapour
Power
Hydrogen fuel cell technology can transform transportation, space exploration, and city power on a global scale by using hydrogen as fuel for an efficient and emission-free electrochemical process. Waste products are only water and heat. NASA has used liquid hydrogen to power its rockets and provide drinking water for crew members since the 1970s.
A hydrogen fuel cell operates like a battery by converting energy from a chemical reaction into usable electric power. Oxygen and hydrogen atoms combine in an electrochemical cell to produce electricity, heat, and water. Unlike a battery, a fuel cell continuously produces energy as long as fuel (hydrogen) is supplied.
Various types of hydrogen fuel cells are available for different applications. Small fuel cells can power cell phones, laptops, and military devices, while larger fuel cells can provide electricity to power grids, back up buildings, or generate electricity in remote areas.
Compared to other energy sources, including green energy solutions, hydrogen fuel cells demonstrate superior performance. They achieve increased fuel efficiency, resulting in more energy output per unit of fuel.
Hydrogen fuel cell power units have an incredibly rapid charging time. Whereas charging an electric vehicle can take 30 minutes to several hours, hydrogen fuel cells can be recharged in less than five minutes. Thanks to this short charging period, hydrogen-powered vehicles offer the same level of flexibility as conventional cars.
Locally generated and stored hydrogen may serve as a practical substitute for diesel-based electricity and heating in remote areas. Such a transition would minimize the need for fuel transportation while providing inhabitants with an eco-friendly, abundant fuel source that enhances their quality of life.
Hydrogen is a colorless, odorless gas stored in compressed cylinders. It has a high energy density, is environmentally safe, and non-toxic to humans. Electrolysis can produce hydrogen from renewable sources, such as wind and solar, in a carbon dioxide-neutral and efficient manner.
The process works by reversing the current direction to consume or release electrical energy, based on the same electrochemical principle used in water electrolysis and fuel cell reactions.