Red Copper Wire Mesh is a metal mesh made from high-purity copper (Cu ≥ 99.9%). It features excellent electrical conductivity, thermal conductivity, ductility, and corrosion resistance. The mesh is produced using either woven or perforated techniques, resulting in uniform mesh openings and a stable structure. Due to its exceptional durability and antibacterial properties, red copper wire mesh is widely used across industries such as electronics, electrical, chemical, construction, and even for decorative purposes.

Epoxy Coated Wire Mesh is a metal mesh with a high-quality epoxy resin coating applied to the surface, typically using carbon steel, stainless steel, or aluminum wire as the base material. The coating enhances its resistance to corrosion and chemicals. Epoxy coated mesh offers excellent corrosion resistance, oxidation resistance, and good mechanical properties, making it ideal for use in filtration systems, HVAC and ventilation equipment, building protection, and industrial equipment. It is particularly suited for applications requiring long-lasting durability and high corrosion resistance.

Hastelloy Wire Mesh is a metallic mesh made from high-performance Hastelloy wire, either woven or welded, featuring exceptional corrosion resistance, high-temperature tolerance, and excellent mechanical strength. Hastelloy is a superalloy containing elements like nickel, molybdenum, and chromium, known for its outstanding stability in a wide range of corrosive environments. Therefore, Hastelloy mesh is widely used in chemical processing, pharmaceuticals, aerospace, marine engineering, and other fields.

Monel Wire Mesh is made from high-purity Monel alloy wire (such as Monel 400, Monel K500) through weaving or welding. It offers exceptional corrosion resistance, good mechanical properties, and high-temperature stability. Monel is a nickel-copper alloy that remains stable in a variety of corrosive environments, particularly excelling in seawater and acidic media. Thanks to its outstanding anti-corrosion properties, Monel mesh is widely used in marine engineering, chemical processing, petroleum refining, and nuclear industries.

Silver Expanded Metal Mesh is a metallic mesh material made from high-purity silver sheets through cutting and expanding processes. Silver expanded metal mesh combines the excellent electrical conductivity, thermal conductivity, and high reflectivity of silver with a unique mesh structure, making it an ideal choice for applications in electromagnetic shielding, chemical catalysis, medical devices, and high-end decorative uses. Its porous design provides excellent breathability and high strength, making it particularly suitable for environments that require efficient conductivity and antibacterial properties.

Silver Wire Mesh is a metallic mesh material made from high-purity silver wire, either woven or welded. It features outstanding electrical and thermal conductivity, as well as natural antibacterial properties. Silver mesh is widely used in electronics manufacturing, electromagnetic shielding, medical devices, chemical catalysis, and other fields due to its excellent physical and chemical properties. Its unique porous structure, combined with silver's high reflectivity and biocompatibility, makes it an irreplaceable material for various precision and high-performance applications.

Copper foam is an advanced functional material made from high-purity copper with a three-dimensional porous structure. It combines lightweight, high electrical conductivity, excellent thermal conductivity, and high porosity, making it a versatile advanced material widely used in batteries, catalysis, thermal management, filtration, and other fields. Copper foam's pore structure can be open-cell, allowing it to perform excellently in fluid transport, electrochemical reactions, and heat 

Ultra-Thick Copper Foam is a porous material made from high-purity copper (typically Cu ≥ 99.9%) using a specialized foaming process. It features excellent electrical conductivity, thermal conductivity, chemical stability, and a large specific surface area. Compared to standard copper foam, ultra-thick copper foam has significantly increased thickness, usually over 10 mm, providing enhanced mechanical strength and durability. This makes it especially suitable for applications that require high strength, stability, and long service life. Ultra-thick copper foam is highly effective in fields such as new energy batteries, electromagnetic shielding, catalyst supports, and heat exchange.

Ultra-thin copper foam is an advanced porous metal material with thickness precisely controlled at the micron level, made from high-purity copper through a special process. It features a three-dimensional porous structure, high electrical conductivity, and a large specific surface area, making it suitable for a wide range of applications that require lightweight materials, high conductivity, and efficient thermal management. Ultra-thin copper foam is widely used in electronics, batteries, catalyst supports, heat dissipation, and filtration fields.

Iron-Nickel Foam is a porous material made from an iron and nickel alloy through a foaming process. It features excellent mechanical strength, conductivity, magnetic properties, and a large specific surface area. Combining the mechanical properties of iron with the corrosion resistance of nickel, iron-nickel foam is a highly functional material used in battery electrodes, electromagnetic shielding, catalyst supports, hydrogen production, and energy absorption materials. With its stable structure, low density, and high porosity, iron-nickel foam has found extensive applications in renewable energy and environmental technologies.

Battery nickel foam is a porous structure made from high-purity nickel material, widely used as an electrode material in batteries. Its three-dimensional open-cell structure provides greater specific surface area and higher electron and ion conductivity for battery reactions, significantly enhancing overall battery performance. Due to its outstanding electrochemical properties, battery nickel foam is a critical component in various battery types, including nickel-metal hydride (Ni-MH), nickel-cadmium (Ni-Cd), and lithium-ion batteries.

Nickel foam for hydrogen production is a highly efficient electrochemical catalyst material made of high-purity nickel with a three-dimensional porous structure and an extremely high specific surface area. This nickel foam is widely used as a catalyst or catalyst support in hydrogen production processes such as water electrolysis and reforming. Its unique physical and chemical properties provide excellent catalytic activity and durability in hydrogen production.

Nickel mesh for hydrogen production is a porous metal material made of high-purity nickel, specifically designed for electrochemical applications such as water electrolysis for hydrogen production. It has excellent electrical conductivity, corrosion resistance, and mechanical strength. The mesh structure provides a large specific surface area, which helps enhance the efficiency of electrolysis, making it an ideal electrode material for hydrogen production. Nickel mesh is widely used in water electrolysis, fuel cells, and other electrochemical reaction fields.

Nickel sintered mesh is a porous metal material made from multiple layers of high-purity nickel mesh through a high-temperature sintering process. The sintering process permanently bonds the metal mesh layers together, forming a solid and stable multilayer structure. Nickel sintered mesh combines the high electrical conductivity, excellent corrosion resistance, and superior mechanical properties of nickel, making it suitable for demanding industrial environments such as filtration, catalysis, battery applications, and high-temperature gas treatment.

Knitted nickel mesh is a mesh-like metal material made from high-purity nickel wires through a knitting process. It features excellent flexibility, electrical conductivity, and corrosion resistance. Due to its unique knitted structure, knitted nickel mesh has three-dimensional porosity and good mechanical properties, making it perform exceptionally well in fields such as electrochemistry, filtration, gas-liquid separation, shielding, and shock absorption. Knitted nickel mesh combines the excellent properties of traditional nickel wire mesh with the flexibility of the knitting process, making it an ideal choice for demanding environments and multifunctional applications.

Nickel felt is a metal fiber material made from high-purity nickel fibers through a non-woven process, featuring a three-dimensional porous structure and a very high specific surface area. Nickel felt retains the high electrical conductivity, excellent corrosion resistance, and good mechanical properties of nickel, while also being lightweight, breathable, and flexible. Its unique structure makes nickel felt highly effective in applications such as battery electrodes, fuel cells, catalyst supports, high-temperature filtration, and electromagnetic shielding, making it a multifunctional, high-performance material.

Titanium Felt is a porous material made from titanium fibers, processed through a sintering technique. It has a unique three-dimensional mesh structure, offering a high specific surface area, excellent mechanical strength, corrosion resistance, and high-temperature stability. Combining the chemical stability of titanium with the flexibility of felt materials, titanium felt is widely used in hydrogen fuel cells, filtration systems, catalyst supports, and electrolytic systems, especially in applications requiring high electrical conductivity and chemical stability.

Titanium foam is a three-dimensional porous metal material made from high-purity titanium, featuring unique properties such as lightweight, high strength, excellent corrosion resistance, and good biocompatibility. Its porous structure and superior mechanical properties make it an ideal material for many advanced applications, including aerospace, biomedical, chemical, energy storage, and catalysis.

Nickel Foam is a high-porosity metal material with excellent electrical conductivity, corrosion resistance, and lightweight properties. It is widely used in battery electrodes, catalyst carriers, filtration systems, electromagnetic shielding, and hydrogen production. We provide nickel foam in various pore sizes and thicknesses to meet diverse industrial requirements.

Key Features:

✅ High Porosity – Uniform structure with excellent permeability
✅ Superior Electrical Conductivity – Ideal for batteries, supercapacitors, and hydrogen electrolysis
✅ Corrosion Resistance – Suitable for harsh environments, enhancing material stability
✅ Lightweight & Durable – Ensures long-lasting performance
✅ High Surface Area – Promotes catalytic reactions and increases hydrogen production efficiency

Nickel Foam is a high-porosity metal material with excellent electrical conductivity, corrosion resistance, and lightweight properties. It is widely used in battery electrodes, catalyst carriers, filtration systems, electromagnetic shielding, and hydrogen production. We provide nickel foam in various pore sizes and thicknesses to meet diverse industrial requirements.

Key Features:

✅ High Porosity – Uniform structure with excellent permeability
✅ Superior Electrical Conductivity – Ideal for batteries, supercapacitors, and hydrogen electrolysis
✅ Corrosion Resistance – Suitable for harsh environments, enhancing material stability
✅ Lightweight & Durable – Ensures long-lasting performance
✅ High Surface Area – Promotes catalytic reactions and increases hydrogen production efficiency

Platinum-coated titanium felt is a highly conductive and corrosion-resistant material used in hydrogen production, electrolysis, fuel cells, and PEM electrolyzers. It enhances catalytic efficiency and durability, making it ideal for high-performance energy applications. Custom sizes and specifications are available for industrial use.

Iridium-Coated Titanium Felt is a high-performance porous material designed for electrolysis, hydrogen production, and fuel cells. It features a titanium felt substrate with a uniform iridium coating, offering excellent corrosion resistance, high electrical conductivity, and superior catalytic activity. This material is widely used in proton exchange membrane (PEM) electrolyzers, fuel cells, and oxygen evolution reaction (OER) applications, ensuring high efficiency and long-term durability.

We provide customized sizes, pore structures, and iridium loadings to meet specific industrial and research needs. Contact us for more details!

Platinum-Plated Titanium Foam is a high-performance porous material featuring a titanium foam substrate uniformly coated with high-purity platinum. It offers excellent corrosion resistance, high electrical conductivity, and superior catalytic activity, making it ideal for applications in water electrolysis, hydrogen production, fuel cells, PEM electrolyzers, and electrochemical catalysis.

We offer customized pore sizes, thicknesses, and platinum loadings to meet various industrial and research needs. Contact us for more details!

Iridium-Plated Foam Titanium is a high-performance porous material designed for hydrogen production, electrolysis, and fuel cells. It features a titanium foam structure coated with high-purity iridium, providing superior corrosion resistance, excellent conductivity, and enhanced catalytic efficiency. This material is widely used in PEM electrolyzers, fuel cells, and advanced electrochemical applications.

We offer customized sizes, pore structures, and iridium loadings to meet specific industrial and research needs. Contact us for more details!

Platinum-Plated Titanium Mesh is a high-performance electrode material featuring a titanium mesh substrate coated with high-purity platinum. It provides excellent corrosion resistance, high electrical conductivity, and superior catalytic efficiency, making it ideal for water electrolysis, hydrogen production, fuel cells, and catalyst support applications.

Due to its lightweight and durable structure, platinum-plated titanium mesh ensures long-term stability in acidic and alkaline environments, making it a preferred choice for PEM electrolyzers, fuel cells, and other electrochemical systems.

We offer customized mesh sizes, platinum loadings, and thicknesses to meet various industrial and research needs. Contact us for more details!

Iridium plated titanium mesh is a corrosion-resistant and high-conductivity material widely used in electrolysis, water treatment, and cathodic protection. The titanium base ensures durability, while the iridium coating enhances conductivity and lifespan.

Platinum-coated titanium felt is a highly conductive and corrosion-resistant material used in hydrogen production, electrolysis, fuel cells, and PEM electrolyzers. It enhances catalytic efficiency and durability, making it ideal for high-performance energy applications. Custom sizes and specifications are available for industrial use.

Platinum-Plated Titanium Foam is a high-performance porous material featuring a titanium foam substrate uniformly coated with high-purity platinum. It offers excellent corrosion resistance, high electrical conductivity, and superior catalytic activity, making it ideal for applications in water electrolysis, hydrogen production, fuel cells, PEM electrolyzers, and electrochemical catalysis.

We offer customized pore sizes, thicknesses, and platinum loadings to meet various industrial and research needs. Contact us for more details!

Iridium-Plated Foam Titanium is a high-performance porous material designed for hydrogen production, electrolysis, and fuel cells. It features a titanium foam structure coated with high-purity iridium, providing superior corrosion resistance, excellent conductivity, and enhanced catalytic efficiency. This material is widely used in PEM electrolyzers, fuel cells, and advanced electrochemical applications.

We offer customized sizes, pore structures, and iridium loadings to meet specific industrial and research needs. Contact us for more details!

Platinum-Plated Titanium Mesh is a high-performance electrode material featuring a titanium mesh substrate coated with high-purity platinum. It provides excellent corrosion resistance, high electrical conductivity, and superior catalytic efficiency, making it ideal for water electrolysis, hydrogen production, fuel cells, and catalyst support applications.

Due to its lightweight and durable structure, platinum-plated titanium mesh ensures long-term stability in acidic and alkaline environments, making it a preferred choice for PEM electrolyzers, fuel cells, and other electrochemical systems.

We offer customized mesh sizes, platinum loadings, and thicknesses to meet various industrial and research needs. Contact us for more details!