Titanium Expanded Mesh 3*6mm Hole 1mm Thickness for Fuel Cell, this product is specially designed for fuel cells. Made of high-quality titanium material, this stretch mesh has excellent corrosion resistance and excellent mechanical properties, providing stable and reliable performance for fuel cell systems. Parameter Material: GR1 titanium Size: 200x200mm Pore size: 3x6mm, 2x3mm or customized Thickness: 1mm, 0.5mm or customized Technique: expanding Features 1. This titanium stretch mesh is made of high-quality titanium material, which has excellent corrosion resistance and excellent mechanical properties. The titanium material itself has the characteristics of low density and high strength, allowing the stretch mesh to maintain stability and durability in long-term use. 2. The moderate hole diameter of 3*6mm can ensure the free flow of gas and liquid in the fuel cell system. This appropriate mesh size helps achieve good gas diffusion and fluid distribution, thereby improving fuel cell efficiency and performance. 3.The thickness of 3.1mm provides this stretch mesh with sufficient strength and structural stability. It is able to withstand the stress and pressure in the fuel cell system while maintaining shape stability and not easily deformed or damaged. This titanium stretch mesh is precision manufactured with an excellent surface finish and meticulous detail. It exhibits high-quality appearance and workmanship while also meeting fuel cell system requirements for material purity and cleanliness. The Application in the Fuel Cell 1.Electrode Support Material: The titanium expanded mesh serves as a reliable support material for fuel cell electrodes, ensuring uniform distribution and strong contact. Its mesh structure enables efficient gas diffusion and electrolyte transport. 2.Flow Field Plate: The mesh is utilized in the flow field plates of fuel cells, facilitating the flow and distribution of fuel gas and oxygen. With its carefully designed hole size and thickness, it promotes effective gas flow and provides structural stability. 3.Catalyst Layer Support: The mesh can be employed as a support material for the oxygen reduction reaction (ORR) catalyst layer. Its high surface area and excellent conductivity enhance catalyst adhesion and electron transfer, improving the efficiency of the ORR.