The increasing awareness of the emerging environmental and climate change effects has led to a global commercialization of clean energy. The demand for powering up several small-scale and low power devices has increased. However, the small-scale storage of electricity has encountered bottlenecks, encouraging the possibility of generating electricity from hydrogen, using fuel cells. Small-scale Proton Exchange Membrane Fuel Cells (PEMFCs) are promising electrochemical cells that convert the chemical energy of fuel into electrical energy. In particular, the small-scale PEMFC (10 kW) is appropriate for applications such as portable power generation, unmanned aerial vehicles (UAV), light-duty vehicles, and residential power supply.
Trends and Challenges in PEMFCs
Professor Kui Jiao and his team from Tianjin University, China, reviewed the advances and challenges in the applications of PEMFCs. Their findings were made available in Energy Reviews. In the review article, the team discusses the operation and characteristics of PEMFCs for applications in the transportation, stationary, and portable power generator fields. In addition, they provide their perspectives on future strategies for small-scale high-specific-power PEMFC’ systems.
Transportation is one of the fields where PEMFCs could be implemented. The successful implementation of small-scale PEMFCs in UAVs, underwater vehicles, and light traction vehicles can make them an excellent alternative power source. The team also added that higher power density, longer endurance, mild hybrid architecture, and PEMFC range extenders are more suitable for small transportation applications.
Small-scale PEMFCs are also used for stationary applications, such as powering up uninterrupted power supply and residential co-generation systems. In this regard, the research team concluded that the PEMFC could be used as a renewable backup power source due to its high efficiency and low pollution emissions. They also addressed fuel flexibility and reliability issues.
Portable power generation is best suited for small-scale PEMFCs due to their longer duration, high energy density, off-grid power generation, and adaptability. Although lithium (Li)-ion battery systems dominate the market in portable applications, small-scale PEMFCs have additional benefits.
Future challenges in the development of small-scale PEMFCs will primarily be associated with optimizing fuel cell materials and the system design to obtain a high-specific power fuel cell. Lightweight components play a crucial role in achieving advanced, high-performance PEMFC technologies by optimizing the structural material design for greater reliability. The response time of PEMFCs can be decreased by using lightweight hybrid power sources for instant power surge.
Furthermore, proper energy management strategies for hybrid power sources help improve their efficiency and dynamics. A hydrogen storage system with a high hydrogen storage density, quick hydrogen release and charge rates, strong reversibility, and improved safety is crucial for increasing the overall device-level energy density of small-scale PEMFC systems. Hence, a compressed gas storage tank of large volume would not be beneficial for small-scale PEMFC applications where space and weight are important parameters. A long-term hydrogen storage system for small-scale PEMFC applications may instead be based on materials such as complex hydrides and metal storage systems with high volumetric densities.
Although several pioneering studies have been conducted to promote the application of small PEMFCs, further advancements are essential to meet the requirements for practical applications. Professor Jiao and his team have addressed the current trends and challenges in PEMFCs and provided a perspective on future strategies for small-scale high-specific-power PEMFC’ systems. Small-scale PEMFCs are a promising alternative power source, and their market uptake can be improved with improvements in their specific power.
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