The alcohol-resistant series of black conductive fabrics are made by coating the surface of polyester fibers with metals such as copper and nickel, followed by treating a single surface with a black water-based graphene electromagnetic shielding coating. (1) The combination of copper and nickel provides excellent conductivity. (2) The inherent conductive properties of the graphene electromagnetic shielding coating can greatly enhance the conductivity of the composite material, achieving good shielding effectiveness in the frequency range from 10MHz to 3GHz. (3) The polymer coating is resistant to some solvents like alcohol, which can meet special process requirements. (4) The blackening treatment also has properties such as light shielding, oxidation resistance, corrosion resistance, and fingerprint resistance.

The alcohol-resistant series of black conductive fabrics are made by coating the surface of polyester fibers with metals such as copper and nickel, followed by treating a single surface with a black water-based graphene electromagnetic shielding coating. (1) The combination of copper and nickel provides excellent conductivity. (2) The inherent conductive properties of the graphene electromagnetic shielding coating can greatly enhance the conductivity of the composite material, achieving good shielding effectiveness in the frequency range from 10MHz to 3GHz. (3) The polymer coating is resistant to some solvents like alcohol, which can meet special process requirements. (4) The blackening treatment also has properties such as light shielding, oxidation resistance, corrosion resistance, and fingerprint resistance.

The 30-micron wear-resistant black conductive fabric is a high-performance composite material. It uses polyester fiber as the base material, with copper-nickel alloy coated on both sides to provide basic conductivity (surface resistance ≤ 0.05Ω), and a black water-based graphene coating applied on one side. Its core structure consists of a black wear-resistant surface (matte black) paired with a silver-gray conductive surface, offering double-sided conductive functionality. The actually measured thickness of the product is 33-34μm, featuring excellent conductive performance. Its matte black surface presents a low-gloss effect (glossiness 3.2-3.4gs) with stable color (color difference values 25.74/0.05/0.12), and special emphasis is placed on its wear-resistant property. This conductive fabric is manufactured using a pure water-based environmental protection coating process, ensuring no VOC residues and meeting safety and environmental protection requirements. The product has a width of 1100±20mm, which can be directly die-cut or laminated with adhesive tape for easy integration and application. It is suitable for electronic application scenarios such as electromagnetic shielding and grounding that require high conductivity, wear resistance and environmental protection.

White conductive cloth is a flexible shielding material with conductive properties, composed of multiple layers of fiber materials, conductive materials, and functional materials. Its chromaticity L value can be close to that of ivory white. In addition to having the same characteristics as black conductive cloth, it can also be used to make white shielding and light-shielding curtains, shielding clothing, household items, etc., as well as white shielding partitions, shielding wallpapers and other products.

The blackened light-shielding series of double-sided black conductive cloth is made by coating the surface of polyester fibers with metals such as copper and nickel, followed by treating both surfaces with a black water-based graphene electromagnetic shielding coating. (1) The combination of copper and nickel provides excellent conductivity. (2) The inherent conductive property of the graphene electromagnetic shielding coating can significantly enhance the conductivity of the composite material, and good shielding effectiveness can be achieved in the frequency range from 10MHz to 3GHz. (3) The blackening treatment also has properties such as light shielding, oxidation resistance, corrosion resistance, and fingerprint resistance.

The 20-micron wear-resistant black conductive cloth is a high-performance composite material. It uses polyester fiber as the base material, with both sides coated with copper-nickel alloy to provide basic conductivity (surface resistance ≤ 0.05Ω), and one side coated with a black water-based graphene coating. Its core thickness is 25 ± 3 microns (22-28μm), belonging to a thin design. The product has unique double-sided conductive properties: one side is silver-gray, and the other side is regular matte black (with a reddish-black hue and a glossiness of approximately 2.5), and both sides have extremely low surface resistance (≤ 0.05Ω). The surface of this conductive cloth has undergone wear-resistant treatment, which significantly improves its durability. It supports direct die-cutting or adhesive processing, with strong process compatibility. Overall, it is a high-performance, environmentally friendly, and easy-to-process thin double-sided conductive material. Moreover, it can be custom-developed according to specific customer needs.

The 50-micron wear-resistant black conductive cloth is a high-performance composite material. It uses polyester fiber as the base material, with both sides coated with copper-nickel alloy to provide basic conductivity (surface resistance ≤ 0.05Ω), and one side coated with a black water-based graphene coating. The conventional black conductive cloth, with a thickness of 53±3μm, features ultra-low surface resistance (≤0.05Ω) and excellent wear resistance. Its surface is flat, smooth, free of impurities and defects, with neat edges without damage. It meets strict gloss standards (3±1gs) and color difference standards (Lab values: 26.55/0.09/-0.25). Adopting a purely water-based environmental protection coating process, it has no VOC residues, supports direct die-cutting or composite adhesive processing, and is suitable for the needs of efficient production lines.

The 12μm alcohol-resistant black conductive non-woven fabric is a high-performance material that is ultra-thin, double-sided conductive (silver-gray surface/matte black surface) and has an extremely low surface resistance (≤0.05Ω). Its black surface is neutral matte black with a color difference of 25.22/-0.16/-0.91. The surface coating of this material is alcohol-resistant and wear-resistant, and can be directly die-cut or glued, making it easy to process. It adopts an environmentally friendly pure water-based coating process with no VOC residues. It is especially suitable for application scenarios with strict requirements on thickness, conductivity, durability, environmental protection and easy processability, such as precision electronic components, electromagnetic shielding, sensors, medical equipment and other fields.

The 80-micron wear-resistant black conductive cloth is a high-performance composite material based on polyester fibers, with both sides coated with copper-nickel alloy to provide basic conductivity (surface resistance ≤ 0.05Ω) and one side coated with a black water-based graphene coating. It has a thickness of 83-85μm, a surface resistance of ≤ 0.05Ω, a glossiness of 0.3-0.4gs, and stable color difference values (24.18/0.22/0.27), presenting a deep black matte appearance. Adopting a pure water-based coating process, it has no VOC residues and can be directly die-cut or used with an adhesive layer. The product complies with the GB/T 30139-2013 standard, with an adhesion of ≥ grade 5 , a width of 1100±20mm, and a grammage of 63±3g/㎡, and it boasts excellent flatness and edge integrity.

Gold conductive fabric is a flexible shielding material with conductive properties, which is composed of multiple layers of fiber materials, conductive materials and functional materials. It is made by coating copper and nickel metals on the surface of the fabric base, followed by treatment with water-based graphene electromagnetic shielding coating. It can be made into electromagnetic shielding devices such as conductive fabric tapes, die-cut materials of various shapes, and conductive gaskets of various shapes by coating PU sponges.