A fuel cell is a device that makes electricity from fuel and air. Instead of burning the fuel to make heat to drive a mechanical generator, fuel cells react the fuel and air electrochemically, without combustion. The electrochemical approach avoids pollutants that are created by high flame temperatures, and it is a more direct and efficient way to make power from a fuel.
Fuel cells are configured in stacks of individual cells connected in a series. FuelCell Energy’s carbonate stacks have up to 400 cells per stack and produce between 250 kW and 400 kW of power. FuelCell Energy’s standard MW-scale module contains four stacks, nets around 1.4 MW of power, and can make electricity for sites like universities or hospitals. Fuel cell technology has powered everything from laptops to space shuttles. The modular design of fuel cell plants lets them scale up to a site’s energy needs. In South Korea, one fuel cell park produces 59 MW of power.
A fuel cell power plant is made up of one or more fuel cell modules. The plant also has electrical and mechanical systems that deliver gasses to and from the stack module and to convert the DC fuel cell power to AC power at the desired voltage. The small footprint, quiet operation, and clean emissions profile make them ideal for highly populated areas. FuelCell Energy’s plants are designed to be safe, clean, reliable, and highly efficient.
Reacting fuel and air electrochemically involves delivering fuel to a set of negative electrodes (called anodes) and delivering air to a set of positive electrodes (called cathodes). The electrochemical reaction of fuel produces electrons.
The electrochemical reaction of oxygen in air consumes electrons. Connecting the two produces the current of usable electrical power. All fuel cells contain a layer between the electrodes called an electrolyte layer.
The electrolyte has ions that move between the fuel and air electrodes to keep charge neutral between the electrodes as they produce and consume electrons. FuelCell Energy’s carbonate platform gets its name from its electrolyte. The electrolyte is made from potassium and lithium carbonates, and carbonate ions are what migrate between the fuel and air electrodes.
Carbonate fuel cells operate at a relatively high temperature, about 1000 degrees F. Operating at high temperature allows the electrode reactions to proceed efficiently without expensive platinum-type catalysts. It also is a high enough temperature that allows the conversion of methane to hydrogen (called reforming) in the fuel cell stack. This allows the cell to generate hydrogen directly from a methane-based fuel source like natural gas or biogas. Availability of natural gas and biogas makes fuel cells an attractive energy solution.
How a fuel cell works
Once methane is converted to hydrogen inside the cells, the hydrogen is reacted to produce electrons, as described above. The reforming reaction also produces carbon dioxide. The high efficiency of fuel cells mean they emit less carbon dioxide per kWh of power generation than other fuel-based power systems, and if the fuel is biogas the power is carbon neutral. The fact that the carbon dioxide is produced in the fuel electrodes before being mixed with diluting air means that it can be easily extracted before being exhausted, to avoid the emission or to provide carbon dioxide to a user as an industrial gas.
This combustion-free process emits water, not pollutants, supporting our customer’s net-zero goals and contributing to local air quality. Some U.S. states have already classified certain fuel cells as Class I renewable power generation due to their low carbon emissions, negligible criteria pollutants, and high efficiency.
In addition to allowing the reforming of methane inside the fuel cells, the high operating temperature improves the efficiency of power generation and provides high grade waste heat for combined heat and power (CHP) operation. The high-quality thermal energy can be used for heating and cooling processes. The electrical efficiency of our carbonate fuel cell solutions ranges from approximately 47% to 60% upon initial operations of our platforms depending on the configuration. When configured for CHP, our system efficiencies can reach up to 90 percent in the right application.
Our solutions are designed to deliver high electrical efficiency where the power is used, avoiding transmission. Transmission line losses average about 5% for the U.S. grid, which represents inefficiency, results in additional emissions, and is a hidden cost to ratepayers. In addition, overhead transmission lines have contributed to the ignition of wildfires in certain geographies. Fuel cells avoid transmission, distribution costs, and other issues by delivering power efficiently at the point of use, which can also increase a site’s energy resilience.
Fuel cells generate clean power and improve dirty sources of generation. Using biogas in a fuel cell plant avoids combustion and reduces landfilled waste. At the same time, carbonate fuel cells are the only known platform that can capture carbon from an external source while generating power. Fossil fuel emissions from boilers or power plants contain high concentrations of CO2. When those exhaust streams are fed into the fuel cell’s cathode, the CO2 is concentrated as it cycles through the cell and can be easily captured. Once the CO2 is captured, it can be sequestered or sold for many industrial uses.
Hydrogen production is key to advancing intermittent renewables like wind and solar. FuelCell Energy’s platforms, both current and in development, can provide power during undersupply and store power during oversupply. A process called “electrolysis” uses power to produce hydrogen, an energy carrier. Stored energy can be transported for use elsewhere. So, the energy from sources like wind and solar can be available for use anytime, anywhere.
Contact us today to learn more about FuelCell Energy’s platforms.