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.

Anti-permeation fiberglass cloth is a high-performance composite material that skillfully combines the physical strength and stability of glass fiber cloth with the electromagnetic shielding and anti-permeation sealing capabilities of functional conductive coatings. Its core advantage lies in simultaneously providing reliable electromagnetic interference protection and tight physical/chemical environment isolation, and it has irreplaceable value especially in application scenarios requiring high reliability, resistance to harsh environments, lightweight properties, and flame retardancy. It is one of the ideal choices for solving complex electromagnetic compatibility and environmental sealing challenges.

Organosilicon - shielded fiberglass cloth is a flexible composite material made by coating high - strength fiberglass cloth with organosilicon rubber. It has excellent electromagnetic shielding effectiveness, adaptability to extreme environments and multiple protective properties. Conductive particles can be incorporated into its coating to form an electromagnetic wave reflection layer. Combined with the dielectric insulation of fiberglass, it can effectively isolate signal interference. At the same time, it has the advantages of high temperature resistance, fire resistance and flame retardancy, corrosion resistance, water resistance, flexibility and easy processing. It is widely used in shielding covers for precision electronic equipment, protection of high - temperature industrial pipelines, cabin gaskets in aerospace, and building fire protection systems. It is an integrated solution to meet the needs of electromagnetic compatibility and physical protection in complex environments.

Organosilicon Shield conductive fabric is a high-performance composite electromagnetic shielding material, which uses polyester fiber as the base material, is coated with copper-nickel alloy on both sides to provide basic conductivity (surface resistance ≤ 0.05Ω), and is coated with an organosilicon shield coating. Its core process is to utilize the flexibility and weather resistance of organosilicon to endow the conductive fabric with stable electromagnetic shielding effectiveness (EMI/RFI shielding) and environmental protection functions, while maintaining the continuity of the conductive network.

Oxford cloth with anti-oxidation property is a functional fabric with a composite structure, which is made by coating anti-oxidation paint on Oxford cloth. Its core breakthrough lies in simultaneously solving the problems of corrosion and electromagnetic shielding attenuation. It has the characteristics of tear resistance, weather resistance and processability, and is specially used in high-demand scenarios such as military tents (anti-electromagnetic eavesdropping), medical shielding curtains (protecting precision instruments), and smart car covers (anti-signal leakage). Its service life is longer than that of traditional shielding materials.

Oxford fabric with flame retardancy is a military functional fabric made by coating a composite flame-retardant layer on a high-density Oxford fabric base. Its core advantage lies in simultaneously achieving UL94 V-0 level flame retardancy and ≥60dB electromagnetic shielding effectiveness (in the 30MHz-10GHz frequency band), while also featuring tear resistance, weather resistance (mildew resistance/UV resistance) and lightweight properties. It is mainly applied in military individual protection, equipment shielding and weapon platforms, etc.

The anti-oxidation TPU composite film is a high-performance material developed on the basis of traditional TPU films through multi-layer composite technology and surface functional coating processes. Its core lies in coating a special anti-oxidation layer on the surface of the TPU substrate to form a composite protection system. This design is mainly aimed at meeting the long-term protection needs of military products in extreme environments such as high salt, high humidity, high heat, and strong ultraviolet rays.