Fuel cell components and materials

Fuel cell systems are considered forward-thinking power generators that produce electrical energy by reversing the process of water electrolysis. This energy can be used to power vehicles, buildings, and other applications. Due to their low emissions and good efficiency, there are numerous international efforts to further develop fuel cell technology. 

High power densities, high energy conversions, and short start-up times (cold start) at low operating temperatures of approximately 60-80 °C often put the focus on the PEM fuel cell (Polymer Electrolyte Membrane Fuel Cell, PEMFC or Proton Exchange Membrane Fuel Cell). A hydrogen fuel cell stack uses pure hydrogen and normal ambient air as an oxidizing agent, making them particularly suitable for stationary power generation systems, battery replacement devices, or fuel cell powered transportation systems.

The optimisation of efficiency through the adjustment of systems and components is central to the further development of fuel cell stacks. Critical factors include operating conditions and potential cost reductions through materials and manufacturing processes. Engineering thermoplastics play a key role in fuel cells. Their easy processability and low weight contribute to significant cost savings, and their very long service life makes them ideal for use in fuel cell systems.

As a leading manufacturer and processor of engineering thermoplastics, we offer comprehensive solutions for fuel cell stacks - from material to component.

As a leading manufacturer and processor of engineering thermoplastics, Ensinger specialises in the development and production of hydrogen fuel cell materials and fuel cell components.

• Our durable and recyclable bipolar plates for fuel cells offer advantageous alternatives compared to metals or thermosets.
• Our TECACOMP HTE materials, developed in collaboration with the Center for Fuel Cell Technology in Duisburg, Germany (ZBT), provide optimised material properties tailored for the bipolar plate in fuel cells.
• Our fuel cell end plate made from TECATRON GF 40 natural or black offer not only advantageous chemical, thermal, and mechanical properties but also excel in high-precision processing.
• Our insulation plates are manufactured according to customer-specific requirements, making them precisely tailored to the application.
• Our Media Supply Units (MSUs) meet the highest standards, contributing to the efficiency and longevity of modern fuel cell systems.

From production to performance - we are your partner for fuel cell technology. For durable, sustainable, and innovative solutions

Together with our partner, the Center for Fuel Cell Technology (ZBT) in Duisburg, Ensinger has developed highly conductive PEM fuel cell materials for bipolar plates. These specially electrically and thermally optimised formulations show their advantages in both stationary and mobile (heavy-duty, rail, and airplane) PEM (Polymer Electrolyte Membrane) applications.
The compounds, available under the brand name TECACOMP HTE, are based on thermoplastic PP (polypropylene) and PPS (polyphenylene sulfide). They have been specifically optimised for the production of PEMFCs in the hot pressing process and are suitable for operating temperatures from 60 °C to 200 °C.

The TECACOMP HTE compounds have already proven themselves under demanding conditions and offer excellent suitability for a wide range of relevant applications. With the compounds of the TECACOMP HTE series, bipolar plates including flow fields can be realised in common sizes up to 950cm² and a thickness of 0,4 mm to 5 mm. Larger dimensions can also be implemented upon request. The PP variant is ideal for direct methanol fuel cells (DMFC), LT-PEM fuel cells, and alkaline fuel cells (AFC), while the PPS variant is suitable for HT-PEM fuel cells and phosphoric acid fuel cells (PAFC).

End plates in fuel cells clamp and fix the fuel cell stack. The contact pressure is crucial for uniform force distribution and leak-free operation of the stack. Insufficient contact pressure between the electrode and the bipolar plate can impair performance due to high contact resistance and losses or even lead to component failure. As stack size increases, so do the requirements for contact pressure. End plates also form the anode and cathode side terminations of the stack, allowing the connection of pipes, cables, and connections for gas, electrolyte, or cooling lines. The performance of the fuel cell stack is significantly influenced by the geometry of the end plate, the connection method, and the materials used.
Metals were primarily used for end plates in the past, despite complex manufacturing processes and high costs. Metal plates also corrode faster, allowing metal ions to diffuse into the electrolyte, which negatively affects conductivity and output voltage. The high thermal conductivity of metallic materials leads to heat loss, requiring more time to reach operating temperature and the use of additional thermal insulators.

Ensinger offers a beneficial alternative with thermoplastic end plates. Our end plates made from glass fiber-reinforced PPS TECATRON GF40 natural or black (semi-finished product) are characterised by excellent chemical resistance, low water absorption, and a low risk of ion leaching. The high mechanical strength and stiffness allow the required contact pressure to be built up in the stack. The high dimensional stability and creep resistance result in very low deformation, even over longer periods under load and at higher temperatures. TECATRON GF40 black also meets the flame resistance requirements of UL94 V-0. Through our established extrusion process, we can significantly reduce stress in materials such as TECATRON GF40 black or natural (PPS GF40), which offers extreme advantages, especially in the machining of end plates.

The complex geometry typical of end plates, with many breakthroughs, pockets, and edge-near holes, poses high demands on machining. Larger components over half a meter in length and significant deviations in the width/length to thickness ratio are not uncommon, posing additional challenges for tools, machines, and expertise. Precision in manufacturing is essential, especially in the prototyping phase, with a view to scaling production towards injection molding.
With high expertise and decades of experience in processing fiber-reinforced plastics, we offer ready-to-install, low-distortion, and high-precision end plates. If you zoom in and rotate, you can take a closer look at Ensinger's end plate made from TECATRON GF40 black: AR Application

Balance of Plant (BOP) refers to additional components and subsystems necessary for the operation of a system. BOP includes, for example, compressors, tanks, and measuring technology for electrolysis, as well as humidifiers and filters in fuel cells. The conditioning of the medium, including piping and valve technology, is also part of the BOP. We are happy to advise you on BOP components individually.

Contact our experts and benefit from our extensive experience and customised solutions for a wide range of applications.